Isolated polynucleotides and polypeptides, and methods of using same for increasing nitrogen use efficiency, yield, growth rate, vigor, biomass, oil content, and/or abiotic stress tolerance

ABSTRACT

Provided are methods of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality and/or abiotic stress tolerance of a plant by expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence at least 80% identical to SEQ ID NO:1-467, 785-3047; or an exogenous polynucleotide encoding a polypeptide at least 80% identical to SEQ ID NO:468-784, 3048-4333, 4335-4682. Also provided isolated polynucleotide comprising a nucleic acid sequence selected from the group consisting of SEQ ID NOs:1-467, 785-3047, which can be used to increase nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality and/or abiotic stress tolerance of a plant.

RELATED APPLICATIONS

This application is a division of U.S. patent application Ser. No. 16/936,493 filed on Jul. 23, 2020, which is a division of U.S. patent application Ser. No. 15/951,258 filed on Apr. 12, 2018, now U.S. Pat. No. 10,791,690, which is a division of U.S. patent application Ser. No. 14/741,477 filed on Jun. 17, 2015, now U.S. Pat. No. 10,006,040, which is a division of U.S. patent application Ser. No. 13/377,556 filed on Dec. 11, 2011, now U.S. Pat. No. 9,096,865, which is a National Phase of PCT Patent Application No. PCT/IB2010/052545 having International Filing Date of Jun. 8, 2010, which claims the benefit of priority of U.S. Provisional Patent Application Nos. 61/272,764 filed on Oct. 30, 2009, and 61/213,457 filed on Jun. 10, 2009.

The contents of the above applications are all incorporated by reference as if fully set forth herein in their entirety.

SEQUENCE LISTING STATEMENT

The ASCII file, entitled 91031SequenceListing.txt, created on Feb. 3, 2022, comprising 8,917,290 bytes, submitted concurrently with the filing of this application is incorporated herein by reference.

FIELD AND BACKGROUND OF THE INVENTION

The present invention, in some embodiments thereof, relates to novel polynucleotides and polypeptides which can increase nitrogen use efficiency, fertilizer use efficiency, yield (e.g., seed/grain yield, oil yield), growth rate, vigor, biomass, oil content, fiber yield, fiber quality and/or length, abiotic stress tolerance and/or water use efficiency of a plant.

A common approach to promote plant growth has been, and continues to be, the use of natural as well as synthetic nutrients (fertilizers). Thus, fertilizers are the fuel behind the “green revolution”, directly responsible for the exceptional increase in crop yields during the last 40 years, and are considered the number one overhead expense in agriculture. Of the three macronutrients provided as main fertilizers [Nitrogen (N), Phosphate (P) and Potassium (K)], nitrogen is often the rate-limiting element in plant growth and all field crops have a fundamental dependence on inorganic nitrogenous fertilizer. Nitrogen usually needs to be replenished every year, particularly for cereals, which comprise more than half of the cultivated areas worldwide. For example, inorganic nitrogenous fertilizers such as ammonium nitrate, potassium nitrate, or urea, typically accounts for 40% of the costs associated with crops such as corn and wheat.

Nitrogen is an essential macronutrient for the plant, responsible for biosynthesis of amino and nucleic acids, prosthetic groups, plant hormones, plant chemical defenses, etc. In addition, nitrogen is often the rate-limiting element in plant growth and all field crops have a fundamental dependence on inorganic nitrogen. Thus, nitrogen is translocated to the shoot, where it is stored in the leaves and stalk during the rapid step of plant development and up until flowering. In corn for example, plants accumulate the bulk of their organic nitrogen during the period of grain germination, and until flowering. Once fertilization of the plant has occurred, grains begin to form and become the main sink of plant nitrogen. The stored nitrogen can be then redistributed from the leaves and stalk that served as storage compartments until grain formation.

Since fertilizer is rapidly depleted from most soil types, it must be supplied to growing crops two or three times during the growing season. In addition, the low nitrogen use efficiency (NUE) of the main crops (e.g., in the range of only 30-70%) negatively affects the input expenses for the farmer, due to the excess fertilizer applied. Moreover, the over and inefficient use of fertilizers are major factors responsible for environmental problems such as eutrophication of groundwater, lakes, rivers and seas, nitrate pollution in drinking water which can cause methemoglobinemia, phosphate pollution, atmospheric pollution and the like. However, in spite of the negative impact of fertilizers on the environment, and the limits on fertilizer use, which have been legislated in several countries, the use of fertilizers is expected to increase in order support food and fiber production for rapid population growth on limited land resources. For example, it has been estimated that by 2050, more than 150 million tons of nitrogenous fertilizer will be used worldwide annually.

Increased use efficiency of nitrogen by plants should enable crops to be cultivated with lower fertilizer input, or alternatively to be cultivated on soils of poorer quality and would therefore have significant economic impact in both developed and developing agricultural systems.

Genetic improvement of fertilizer use efficiency (FUE) in plants can be generated either via traditional breeding or via genetic engineering.

Attempts to generate plants with increased FUE have been described in U.S. Pat. Appl. No. 20020046419 to Choo, et al.; U.S. Pat. Appl. No. 2005010879 to Edgerton et al.; U.S. Pat. Appl. No. 20060179511 to Chomet et al.; Good, A, et al. 2007 (Engineering nitrogen use efficiency with alanine aminotransferase. Canadian Journal of Botany 85: 252-262); and Good A G et al. 2004 (Trends Plant Sci. 9:597-605).

Yanagisawa et al. (Proc. Natl. Acad. Sci. U.S.A. 2004 101:7833-8) describe Dof1 transgenic plants which exhibit improved growth under low-nitrogen conditions.

U.S. Pat. No. 6,084,153 to Good et al. discloses the use of a stress responsive promoter to control the expression of Alanine Amine Transferase (AlaAT) and transgenic canola plants with improved drought and nitrogen deficiency tolerance when compared to control plants.

The ever-increasing world population and the decreasing availability in arable land for agriculture affect the yield of plants and plant-related products. The global shortage of water supply, desertification, abiotic stress (ABS) conditions (e.g., salinity, drought, flood, suboptimal temperature and toxic chemical pollution), and/or limited nitrogen and fertilizer sources cause substantial damage to agricultural plants such as major alterations in the plant metabolism, cell death, and decreases in plant growth and crop productivity.

Drought is a gradual phenomenon, which involves periods of abnormally dry weather that persists long enough to produce serious hydrologic imbalances such as crop damage, water supply shortage and increased susceptibility to various diseases.

Salinity, high salt levels, affects one in five hectares of irrigated land. None of the top five food crops, i.e., wheat, corn, rice, potatoes, and soybean, can tolerate excessive salt. Detrimental effects of salt on plants result from both water deficit, which leads to osmotic stress (similar to drought stress), and the effect of excess sodium ions on critical biochemical processes. As with freezing and drought, high salt causes water deficit; and the presence of high salt makes it difficult for plant roots to extract water from their environment. Thus, salination of soils that are used for agricultural production is a significant and increasing problem in regions that rely heavily on agriculture, and is worsen by over-utilization, over-fertilization and water shortage, typically caused by climatic change and the demands of increasing population.

Suboptimal temperatures affect plant growth and development through the whole plant life cycle. Thus, low temperatures reduce germination rate and high temperatures result in leaf necrosis. In addition, mature plants that are exposed to excess of heat may experience heat shock, which may arise in various organs, including leaves and particularly fruit, when transpiration is insufficient to overcome heat stress. Heat also damages cellular structures, including organelles and cytoskeleton, and impairs membrane function. Heat shock may produce a decrease in overall protein synthesis, accompanied by expression of heat shock proteins, e.g., chaperones, which are involved in refolding proteins denatured by heat. High-temperature damage to pollen almost always occurs in conjunction with drought stress, and rarely occurs under well-watered conditions. Combined stress can alter plant metabolism in novel ways. Excessive chilling conditions, e.g., low, but above freezing, temperatures affect crops of tropical origins, such as soybean, rice, maize, and cotton. Typical chilling damage includes wilting, necrosis, chlorosis or leakage of ions from cell membranes. Excessive light conditions, which occur under clear atmospheric conditions subsequent to cold late summer/autumn nights, can lead to photoinhibition of photosynthesis (disruption of photosynthesis). In addition, chilling may lead to yield losses and lower product quality through the delayed ripening of maize.

Nutrient deficiencies cause adaptations of the root architecture, particularly notably for example is the root proliferation within nutrient rich patches to increase nutrient uptake. Nutrient deficiencies cause also the activation of plant metabolic pathways which maximize the absorption, assimilation and distribution processes such as by activating architectural changes. Engineering the expression of the triggered genes may cause the plant to exhibit the architectural changes and enhanced metabolism also under other conditions.

In addition, it is widely known that the plants usually respond to water deficiency by creating a deeper root system that allows access to moisture located in deeper soil layers. Triggering this effect will allow the plants to access nutrients and water located in deeper soil horizons particularly those readily dissolved in water like nitrates.

Yield is affected by various factors, such as, the number and size of the plant organs, plant architecture (for example, the number of branches), grains set length, number of filled grains, vigor (e.g. seedling), growth rate, root development, utilization of water, nutrients (e.g., nitrogen) and fertilizers, and stress tolerance.

Crops such as, corn, rice, wheat, canola and soybean account for over half of total human caloric intake, whether through direct consumption of the seeds themselves or through consumption of meat products raised on processed seeds or forage. Seeds are also a source of sugars, proteins and oils and metabolites used in industrial processes. The ability to increase plant yield, whether through increase dry matter accumulation rate, modifying cellulose or lignin composition, increase stalk strength, enlarge meristem size, change of plant branching pattern, erectness of leaves, increase in fertilization efficiency, enhanced seed dry matter accumulation rate, modification of seed development, enhanced seed filling or by increasing the content of oil, starch or protein in the seeds would have many applications in agricultural and non-agricultural uses such as in the biotechnological production of pharmaceuticals, antibodies or vaccines.

Studies have shown that plant adaptations to adverse environmental conditions are complex genetic traits with polygenic nature. Conventional means for crop and horticultural improvements utilize selective breeding techniques to identify plants having desirable characteristics. However, selective breeding is tedious, time consuming and has an unpredictable outcome. Furthermore, limited germplasm resources for yield improvement and incompatibility in crosses between distantly related plant species represent significant problems encountered in conventional breeding. Advances in genetic engineering have allowed mankind to modify the germplasm of plants by expression of genes-of-interest in plants. Such a technology has the capacity to generate crops or plants with improved economic, agronomic or horticultural traits.

WO publication No. 2009/013750 discloses genes, constructs and methods of increasing abiotic stress tolerance, biomass and/or yield in plants generated thereby.

WO publication No. 2008/122980 discloses genes constructs and methods for increasing oil content, growth rate and biomass of plants.

WO publication No. 2008/075364 discloses polynucleotides involved in plant fiber development and methods of using same.

WO publication No. 2007/049275 discloses isolated polypeptides, polynucleotides encoding same, transgenic plants expressing same and methods of using same for increasing fertilizer use efficiency, plant abiotic stress tolerance and biomass.

WO publication No. 2004/104162 discloses methods of increasing abiotic stress tolerance and/or biomass in plants and plants generated thereby.

WO publication No. 2005/121364 discloses polynucleotides and polypeptides involved in plant fiber development and methods of using same for improving fiber quality, yield and/or biomass of a fiber producing plant.

WO publication No. 2007/020638 discloses methods of increasing abiotic stress tolerance and/or biomass in plants and plants generated thereby.

WO publication No. 2009/083958 discloses methods of increasing water use efficiency, fertilizer use efficiency, biotic/abiotic stress tolerance, yield and biomass in plant and plants generated thereby.

WO publication No. 2010/020941 discloses methods of increasing nitrogen use efficiency, abiotic stress tolerance, yield and biomass in plants and plants generated thereby.

WO publication No. 2009/141824 discloses isolated polynucleotides and methods using same for increasing plant utility.

SUMMARY OF THE INVENTION

According to an aspect of some embodiments of the present invention there is provided a method of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence at least 80% identical to SEQ ID NO:1-467, 785-3046 or 3047, thereby increasing the nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs:1-467, and 785-3047, thereby increasing the nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least 80% identical to SEQ ID NO:468-784, 3048-4333, 4335-4681 or 4682, thereby increasing the nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, 4335-4682 and 4334, thereby increasing the nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising a nucleic acid sequence at least 80% identical to SEQ ID NO:1-467, 785-3046 or 3047, wherein the nucleic acid sequence is capable of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of a plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs:1-467, and 785-3047.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises an amino acid sequence at least 80% homologous to the amino acid sequence set forth in SEQ ID NO: 468-784, 3048-4333, 4335-4681 or 4682, wherein the amino acid sequence is capable of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises the amino acid sequence selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, 4335-4682 and 4334.

According to an aspect of some embodiments of the present invention there is provided a nucleic acid construct comprising the isolated polynucleotide of some embodiments of the invention and a promoter for directing transcription of the nucleic acid sequence in a host cell.

According to an aspect of some embodiments of the present invention there is provided an isolated polypeptide comprising an amino acid sequence at least 80% homologous to SEQ ID NO:468-784, 3048-4333, 4335-4681 or 4682, wherein the amino acid sequence is capable of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance of a plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polypeptide comprising the amino acid sequence selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, and 4335-4682.

According to an aspect of some embodiments of the present invention there is provided a plant cell exogenously expressing the polynucleotide of some embodiments of the invention, or the nucleic acid construct of some embodiments of the invention.

According to an aspect of some embodiments of the present invention there is provided a plant cell exogenously expressing the polypeptide of some embodiments of the invention.

According to some embodiments of the invention, the nucleic acid sequence is as set forth in SEQ ID NO:1-467, 785-3046 or 3047.

According to some embodiments of the invention, the polynucleotide consists of the nucleic acid sequence selected from the group consisting of SEQ ID NOs:1-467, and 785-3047.

According to some embodiments of the invention, the nucleic acid sequence encodes an amino acid sequence at least 80% homologous to SEQ ID NO:468-784, 3048-4333, 4335-4681 or 4682.

According to some embodiments of the invention, the nucleic acid sequence encodes the amino acid sequence selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, and 4335-4682.

According to some embodiments of the invention, the plant cell forms part of a plant.

According to some embodiments of the invention, the method further comprising growing the plant expressing the exogenous polynucleotide under the abiotic stress.

According to some embodiments of the invention, the abiotic stress is selected from the group consisting of salinity, drought, water deprivation, flood, etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nutrient excess, atmospheric pollution and UV irradiation.

According to some embodiments of the invention, the yield comprises seed yield or oil yield.

According to some embodiments of the invention, the promoter is heterologous to the isolated polynucleotide and/or to the host cell.

Unless otherwise defined, all technical and/or scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of embodiments of the invention, exemplary methods and/or materials are described below. In case of conflict, the patent specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and are not intended to be necessarily limiting.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Some embodiments of the invention are herein described, by way of example only, with reference to the accompanying drawings. With specific reference now to the drawings in detail, it is stressed that the particulars shown are by way of example and for purposes of illustrative discussion of embodiments of the invention. In this regard, the description taken with the drawings makes apparent to those skilled in the art how embodiments of the invention may be practiced.

In the drawings:

FIG. 1 is a schematic illustration of the modified pGI binary plasmid containing the new At6669 promoter (SEQ ID NO:4687) and the GUSintron (pQYN_6669) used for expressing the isolated polynucleotide sequences of the invention. RB—T-DNA right border; LB—T-DNA left border; MCS—Multiple cloning site; RE—any restriction enzyme; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); GUSintron—the GUS reporter gene (coding sequence and intron). The isolated polynucleotide sequences of the invention were cloned into the vector while replacing the GUSintron reporter gene.

FIG. 2 is a schematic illustration of the modified pGI binary plasmid containing the new At6669 promoter (SEQ ID NO:4687) (pQFN) used for expressing the isolated polynucleotide sequences of the invention. RB—T-DNA right border; LB—T-DNA left border; MCS—Multiple cloning site; RE—any restriction enzyme; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); GUSintron—the GUS reporter gene (coding sequence and intron). The isolated polynucleotide sequences of the invention were cloned into the MCS of the vector.

FIGS. 3A-3F are images depicting visualization of root development of transgenic plants exogenously expressing the polynucleotide of some embodiments of the invention when grown in transparent agar plates under normal (FIGS. 3A-3B), osmotic stress (15% PEG; FIGS. 3C-3D) or nitrogen-limiting (FIGS. 3E-3F) conditions. The different transgenes were grown in transparent agar plates for 17 days (7 days nursery and 10 days after transplanting). The plates were photographed every 3-4 days starting at day 1 after transplanting. FIG. 3A—An image of a photograph of plants taken following 10 after transplanting days on agar plates when grown under normal (standard) conditions. FIG. 3B—An image of root analysis of the plants shown in FIG. 3A in which the lengths of the roots measured are represented by arrows. FIG. 3C—An image of a photograph of plants taken following 10 days after transplanting on agar plates, grown under high osmotic (PEG 15%) conditions. FIG. 3D—An image of root analysis of the plants shown in FIG. 3C in which the lengths of the roots measured are represented by arrows. FIG. 3E—An image of a photograph of plants taken following 10 days after transplanting on agar plates, grown under low nitrogen conditions. FIG. 3F—An image of root analysis of the plants shown in FIG. 3E in which the lengths of the roots measured are represented by arrows.

FIG. 4 is a schematic illustration of the modified pGI binary plasmid containing the Root Promoter (pQNa_RP) used for expressing the isolated polynucleotide sequences of the invention. RB—T-DNA right border; LB—T-DNA left border; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); The isolated polynucleotide sequences according to some embodiments of the invention were cloned into the MCS of the vector.

DESCRIPTION OF SPECIFIC EMBODIMENTS OF THE INVENTION

The present invention, in some embodiments thereof, relates to novel polynucleotides and polypeptides, nucleic acid constructs comprising same, host cells expressing same, transgenic plants exogenously expressing same and, more particularly, but not exclusively, to methods of using same for increasing nitrogen use efficiency, fertilizer use efficiency, yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant.

Before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not necessarily limited in its application to the details set forth in the following description or exemplified by the Examples. The invention is capable of other embodiments or of being practiced or carried out in various ways.

The present inventors have identified novel polypeptides and polynucleotides which can be used to increase nitrogen use efficiency, fertilizer use efficiency, yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant.

Thus, as shown in the Examples section which follows, the present inventors have utilized bioinformatics tools to identify polynucleotides which enhance nitrogen use efficiency, fertilizer use efficiency, yield (e.g., seed yield, oil yield), growth rate, vigor, biomass, oil content, fiber development (e.g., fiber yield, quality and/or length), abiotic stress tolerance and/or water use efficiency of a plant. Genes which affect the trait-of-interest were identified based on expression profiles of genes of several Arabidopsis, Rice, Sorghum, Barley, Maize and Tomato ecotypes and tissues (Tables 3-84; Examples 3-16), homology with genes known to affect the trait-of-interest and using digital expression profiles in specific tissues and conditions (Table 1, Example 1). Homologous polypeptides and polynucleotides having the same function were also identified (Table 2, Example 2). Altogether, these results suggest the use of the novel polynucleotides and polypeptides of the invention for increasing nitrogen use efficiency, fertilizer use efficiency, yield (e.g., seed yield, oil yield), growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant.

Thus, according to an aspect of some embodiments of the invention, there is provided method of increasing fertilizer use efficiency, nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence at least 80% identical to SEQ ID NO:1-467, 785-3046 or 3047, thereby increasing the fertilizer use efficiency, nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber length, fiber quality, and/or abiotic stress tolerance of the plant.

As used herein the phrase “fertilizer use efficiency” refers to the metabolic process(es) which lead to an increase in the plant's yield, biomass, vigor, and growth rate per fertilizer unit applied. The metabolic process can be the uptake, spread, absorbent, accumulation, relocation (within the plant) and use of one or more of the minerals and organic moieties absorbed by the plant, such as nitrogen, phosphates and/or potassium.

As used herein the phrase “fertilizer-limiting conditions” refers to growth conditions which include a level (e.g., concentration) of a fertilizer applied which is below the level needed for normal plant metabolism, growth, reproduction and/or viability.

As used herein the phrase “nitrogen use efficiency (NUE)” refers to the metabolic process(es) which lead to an increase in the plant's yield, biomass, vigor, and growth rate per nitrogen unit applied. The metabolic process can be the uptake, spread, absorbent, accumulation, relocation (within the plant) and use of nitrogen absorbed by the plant.

As used herein the phrase “nitrogen-limiting conditions” refers to growth conditions which include a level (e.g., concentration) of nitrogen (e.g., ammonium or nitrate) applied which is below the level needed for normal plant metabolism, growth, reproduction and/or viability.

Improved plant NUE and FUE is translated in the field into either harvesting similar quantities of yield, while implementing less fertilizers, or increased yields gained by implementing the same levels of fertilizers. Thus, improved NUE or FUE has a direct effect on plant yield in the field. Thus, the polynucleotides and polypeptides of some embodiments of the invention positively affect plant yield, seed yield, and plant biomass. In addition, the benefit of improved plant NUE will certainly improve crop quality and biochemical constituents of the seed such as protein yield and oil yield.

As used herein the phrase “plant yield” refers to the amount (e.g., as determined by weight or size) or quantity (numbers) of tissues or organs produced per plant or per growing season. Hence increased yield could affect the economic benefit one can obtain from the plant in a certain growing area and/or growing time.

It should be noted that a plant yield can be affected by various parameters including, but not limited to, plant biomass; plant vigor; growth rate; seed yield; seed or grain quantity; seed or grain quality; oil yield; content of oil, starch and/or protein in harvested organs (e.g., seeds or vegetative parts of the plant); number of flowers (florets) per panicle (expressed as a ratio of number of filled seeds over number of primary panicles); harvest index; number of plants grown per area; number and size of harvested organs per plant and per area; number of plants per growing area (density); number of harvested organs in field; total leaf area; carbon assimilation and carbon partitioning (the distribution/allocation of carbon within the plant); resistance to shade; number of harvestable organs (e.g. seeds), seeds per pod, weight per seed; and modified architecture [such as increase stalk diameter, thickness or improvement of physical properties (e.g. elasticity)].

The term “seed” (also referred to as “grain” or “kernel”) as used herein refers to a small embryonic plant enclosed in a covering called the seed coat (usually with some stored food), the product of the ripened ovule of gymnosperm and angiosperm plants which occurs after fertilization and some growth within the mother plant.

As used herein the phrase “seed yield” refers to the number or weight of the seeds per plant, seeds per pod, or per growing area or to the weight of a single seed, or to the oil extracted per seed. Hence seed yield can be affected by seed dimensions (e.g., length, width, perimeter, area and/or volume), number of (filled) seeds and seed filling rate and by seed oil content. Hence increase seed yield per plant could affect the economic benefit one can obtain from the plant in a certain growing area and/or growing time; and increase seed yield per growing area could be achieved by increasing seed yield per plant, and/or by increasing number of plants grown on the same given area.

The phrase “oil content” as used herein refers to the amount of lipids in a given plant organ, either the seeds (seed oil content) or the vegetative portion of the plant (vegetative oil content) and is typically expressed as percentage of dry weight (10% humidity of seeds) or wet weight (for vegetative portion).

It should be noted that oil content is affected by intrinsic oil production of a tissue (e.g., seed, vegetative portion), as well as the mass or size of the oil-producing tissue per plant or per growth period.

In one embodiment, increase in oil content of the plant can be achieved by increasing the size/mass of a plant's tissue(s) which comprise oil per growth period. Thus, increased oil content of a plant can be achieved by increasing the yield, growth rate, biomass and vigor of the plant.

As used herein the phrase “plant biomass” refers to the amount (e.g., measured in grams of air-dry tissue) of a tissue produced from the plant in a growing season, which could also determine or affect the plant yield or the yield per growing area. An increase in plant biomass can be in the whole plant or in parts thereof such as aboveground (harvestable) parts, vegetative biomass, roots and seeds.

As used herein the phrase “growth rate” refers to the increase in plant organ/tissue size per time (can be measured in cm² per day).

As used herein the phrase “plant vigor” refers to the amount (measured by weight) of tissue produced by the plant in a given time. Hence increased vigor could determine or affect the plant yield or the yield per growing time or growing area. In addition, early vigor (seed and/or seedling) results in improved field stand.

It should be noted that a plant yield can be determined under stress (e.g., abiotic stress, nitrogen-limiting conditions) and/or non-stress (normal) conditions.

As used herein, the phrase “non-stress conditions” refers to the growth conditions (e.g., water, temperature, light-dark cycles, humidity, salt concentration, fertilizer concentration in soil, nutrient supply such as nitrogen, phosphorous and/or potassium), that do not significantly go beyond the everyday climatic and other abiotic conditions that plants may encounter, and which allow optimal growth, metabolism, reproduction and/or viability of a plant at any stage in its life cycle (e.g., in a crop plant from seed to a mature plant and back to seed again). Persons skilled in the art are aware of normal soil conditions and climatic conditions for a given plant in a given geographic location. It should be noted that while the non-stress conditions may include some mild variations from the optimal conditions (which vary from one type/species of a plant to another), such variations do not cause the plant to cease growing without the capacity to resume growth.

The phrase “abiotic stress” as used herein refers to any adverse effect on metabolism, growth, reproduction and/or viability of a plant. Accordingly, abiotic stress can be induced by suboptimal environmental growth conditions such as, for example, salinity, water deprivation, flooding, freezing, low or high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, atmospheric pollution or UV irradiation. The implications of abiotic stress are discussed in the Background section.

The phrase “abiotic stress tolerance” as used herein refers to the ability of a plant to endure an abiotic stress without suffering a substantial alteration in metabolism, growth, productivity and/or viability.

As used herein the phrase “water use efficiency (WUE)” refers to the level of organic matter produced per unit of water consumed by the plant, i.e., the dry weight of a plant in relation to the plant's water use, e.g., the biomass produced per unit transpiration.

It should be noted that improved ABST will confer plants with improved vigor also under non-stress conditions, resulting in crops having improved biomass and/or yield e.g., elongated fibers for the cotton industry, higher oil content.

The term “fiber” is usually inclusive of thick-walled conducting cells such as vessels and tracheids and to fibrillar aggregates of many individual fiber cells. Hence, the term “fiber” refers to (a) thick-walled conducting and non-conducting cells of the xylem; (b) fibers of extraxylary origin, including those from phloem, bark, ground tissue, and epidermis; and (c) fibers from stems, leaves, roots, seeds, and flowers or inflorescences (such as those of Sorghum vulgare used in the manufacture of brushes and brooms).

Example of fiber producing plants, include, but are not limited to, agricultural crops such as cotton, silk cotton tree (Kapok, Ceiba pentandra), desert willow, creosote bush, winterfat, balsa, kenaf, roselle, jute, sisal abaca, flax, corn, sugar cane, hemp, ramie, kapok, coir, bamboo, spanish moss and Agave spp. (e.g. sisal).

As used herein the phrase “fiber quality” refers to at least one fiber parameter which is agriculturally desired, or required in the fiber industry (further described hereinbelow). Examples of such parameters, include but are not limited to, fiber length, fiber strength, fiber fitness, fiber weight per unit length, maturity ratio and uniformity (further described hereinbelow.

Cotton fiber (lint) quality is typically measured according to fiber length, strength and fineness. Accordingly, the lint quality is considered higher when the fiber is longer, stronger and finer.

As used herein the phrase “fiber yield” refers to the amount or quantity of fibers produced from the fiber producing plant.

As used herein the term “increasing” refers to at least about 2%, at least about 3%, at least about 4%, at least about 5%, at least about 10%, at least about 15%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, increase in nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant of a plant as compared to a native plant [i.e., a plant not modified with the biomolecules (polynucleotide or polypeptides) of the invention, e.g., a non-transformed plant of the same species which is grown under the same growth conditions).

The phrase “expressing within the plant an exogenous polynucleotide” as used herein refers to upregulating the expression level of an exogenous polynucleotide within the plant by introducing the exogenous polynucleotide into a plant cell or plant and expressing by recombinant means, as further described herein below.

As used herein “expressing” refers to expression at the mRNA and optionally polypeptide level.

As used herein, the phrase “exogenous polynucleotide” refers to a heterologous nucleic acid sequence which may not be naturally expressed within the plant or which overexpression thereof in the plant is desired. The exogenous polynucleotide may be introduced into the plant in a stable or transient manner, so as to produce a ribonucleic acid (RNA) molecule and/or a polypeptide molecule. It should be noted that the exogenous polynucleotide may comprise a nucleic acid sequence which is identical or partially homologous to an endogenous nucleic acid sequence of the plant.

The term “endogenous” as used herein refers to any polynucleotide or polypeptide which is present and/or naturally expressed within a plant or a cell thereof.

According to some embodiments of the invention the exogenous polynucleotide comprises a nucleic acid sequence which is at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs:1-467, and 785-3047.

Identity (e.g., percent homology) can be determined using any homology comparison software, including for example, the BlastN software of the National Center of Biotechnology Information (NCBI) such as by using default parameters.

According to some embodiments of the invention, the homology is a global homology, i.e., an homology over the entire amino acid or nucleic acid sequences of the invention and not over portions thereof.

According to some embodiments of the invention the exogenous polynucleotide is at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polynucleotide selected from the group consisting of SEQ ID NOs:1-467, and 785-3047.

According to some embodiments of the invention the exogenous polynucleotide is set forth by SEQ ID NO:1-467, 785-3046 or 3047.

As used herein the term “polynucleotide” refers to a single or double stranded nucleic acid sequence which is isolated and provided in the form of an RNA sequence, a complementary polynucleotide sequence (cDNA), a genomic polynucleotide sequence and/or a composite polynucleotide sequences (e.g., a combination of the above).

The term “isolated” refers to at least partially separated from the natural environment e.g., from a plant cell.

As used herein the phrase “complementary polynucleotide sequence” refers to a sequence, which results from reverse transcription of messenger RNA using a reverse transcriptase or any other RNA dependent DNA polymerase. Such a sequence can be subsequently amplified in vivo or in vitro using a DNA dependent DNA polymerase.

As used herein the phrase “genomic polynucleotide sequence” refers to a sequence derived (isolated) from a chromosome and thus it represents a contiguous portion of a chromosome.

As used herein the phrase “composite polynucleotide sequence” refers to a sequence, which is at least partially complementary and at least partially genomic. A composite sequence can include some exonal sequences required to encode the polypeptide of the present invention, as well as some intronic sequences interposing therebetween. The intronic sequences can be of any source, including of other genes, and typically will include conserved splicing signal sequences. Such intronic sequences may further include cis acting expression regulatory elements.

According to some embodiments of the invention, the exogenous polynucleotide of the invention encodes a polypeptide having an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, and 4335-4682.

Homology (e.g., percent homology) can be determined using any homology comparison software, including for example, the BlastP or TBLASTN software of the National Center of Biotechnology Information (NCBI) such as by using default parameters, when starting from a polypeptide sequence; or the tBLASTX algorithm (available via the NCBI) such as by using default parameters, which compares the six-frame conceptual translation products of a nucleotide query sequence (both strands) against a protein sequence database.

Homologous sequences include both orthologous and paralogous sequences. The term “paralogous” relates to gene-duplications within the genome of a species leading to paralogous genes. The term “orthologous” relates to homologous genes in different organisms due to ancestral relationship.

One option to identify orthologues in monocot plant species is by performing a reciprocal blast search. This may be done by a first blast involving blasting the sequence-of-interest against any sequence database, such as the publicly available NCBI database which may be found at: Hypertext Transfer Protocol://World Wide Web (dot) ncbi (dot) nlm (dot) nih (dot) gov. If orthologues in rice were sought, the sequence-of-interest would be blasted against, for example, the 28,469 full-length cDNA clones from Oryza sativa Nipponbare available at NCBI. The blast results may be filtered. The full-length sequences of either the filtered results or the non-filtered results are then blasted back (second blast) against the sequences of the organism from which the sequence-of-interest is derived. The results of the first and second blasts are then compared. An orthologue is identified when the sequence resulting in the highest score (best hit) in the first blast identifies in the second blast the query sequence (the original sequence-of-interest) as the best hit. Using the same rational a paralogue (homolog to a gene in the same organism) is found. In case of large sequence families, the ClustalW program may be used [Hypertext Transfer Protocol://World Wide Web (dot) ebi (dot) ac (dot) uk/Tools/clustalw2/index (dot) html], followed by a neighbor-joining tree (Hypertext Transfer Protocol://en (dot) wikipedia (dot) org/wiki/Neighbor-joining) which helps visualizing the clustering.

According to some embodiments of the invention, the exogenous polynucleotide encodes a polypeptide consisting of the amino acid sequence set forth by SEQ ID NO:468-784, 3048-4333, 4335-4682 or 4334.

Nucleic acid sequences encoding the polypeptides of the present invention may be optimized for expression. Examples of such sequence modifications include, but are not limited to, an altered G/C content to more closely approach that typically found in the plant species of interest, and the removal of codons atypically found in the plant species commonly referred to as codon optimization.

The phrase “codon optimization” refers to the selection of appropriate DNA nucleotides for use within a structural gene or fragment thereof that approaches codon usage within the plant of interest. Therefore, an optimized gene or nucleic acid sequence refers to a gene in which the nucleotide sequence of a native or naturally occurring gene has been modified in order to utilize statistically-preferred or statistically-favored codons within the plant. The nucleotide sequence typically is examined at the DNA level and the coding region optimized for expression in the plant species determined using any suitable procedure, for example as described in Sardana et al. (1996, Plant Cell Reports 15:677-681). In this method, the standard deviation of codon usage, a measure of codon usage bias, may be calculated by first finding the squared proportional deviation of usage of each codon of the native gene relative to that of highly expressed plant genes, followed by a calculation of the average squared deviation. The formula used is: 1 SDCU=n=1 N [(Xn−Yn)/Yn]2/N, where Xn refers to the frequency of usage of codon n in highly expressed plant genes, where Yn to the frequency of usage of codon n in the gene of interest and N refers to the total number of codons in the gene of interest. A Table of codon usage from highly expressed genes of dicotyledonous plants is compiled using the data of Murray et al. (1989, Nuc Acids Res. 17:477-498).

One method of optimizing the nucleic acid sequence in accordance with the preferred codon usage for a particular plant cell type is based on the direct use, without performing any extra statistical calculations, of codon optimization Tables such as those provided on-line at the Codon Usage Database through the NIAS (National Institute of Agrobiological Sciences) DNA bank in Japan (Hypertext Transfer Protocol://World Wide Web (dot) kazusa (dot) or (dot) jp/codon/). The Codon Usage Database contains codon usage tables for a number of different species, with each codon usage Table having been statistically determined based on the data present in Genbank.

By using the above Tables to determine the most preferred or most favored codons for each amino acid in a particular species (for example, rice), a naturally-occurring nucleotide sequence encoding a protein of interest can be codon optimized for that particular plant species. This is effected by replacing codons that may have a low statistical incidence in the particular species genome with corresponding codons, in regard to an amino acid, that are statistically more favored. However, one or more less-favored codons may be selected to delete existing restriction sites, to create new ones at potentially useful junctions (5′ and 3′ ends to add signal peptide or termination cassettes, internal sites that might be used to cut and splice segments together to produce a correct full-length sequence), or to eliminate nucleotide sequences that may negatively effect mRNA stability or expression.

The naturally-occurring encoding nucleotide sequence may already, in advance of any modification, contain a number of codons that correspond to a statistically-favored codon in a particular plant species. Therefore, codon optimization of the native nucleotide sequence may comprise determining which codons, within the native nucleotide sequence, are not statistically-favored with regards to a particular plant, and modifying these codons in accordance with a codon usage table of the particular plant to produce a codon optimized derivative. A modified nucleotide sequence may be fully or partially optimized for plant codon usage provided that the protein encoded by the modified nucleotide sequence is produced at a level higher than the protein encoded by the corresponding naturally occurring or native gene. Construction of synthetic genes by altering the codon usage is described in for example PCT Patent Application 93/07278.

According to some embodiments of the invention, the exogenous polynucleotide is a non-coding RNA.

As used herein the phrase “non-coding RNA” refers to an RNA molecule which does not encode an amino acid sequence (a polypeptide). Examples of such non-coding RNA molecules include, but are not limited to, an antisense RNA, a pre-miRNA (precursor of a microRNA), or a precursor of a Piwi-interacting RNA (piRNA).

Non-limiting examples of non-coding RNA polynucleotides are provided in SEQ ID NOs:214, 215, 216, 466, 467, 967, 968, 969, and 1575.

Thus, the invention encompasses nucleic acid sequences described hereinabove; fragments thereof, sequences hybridizable therewith, sequences homologous thereto, sequences encoding similar polypeptides with different codon usage, altered sequences characterized by mutations, such as deletion, insertion or substitution of one or more nucleotides, either naturally occurring or man induced, either randomly or in a targeted fashion.

The invention provides an isolated polynucleotide comprising a nucleic acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polynucleotide selected from the group consisting of SEQ ID NOs:1-467, and 785-3047.

According to some embodiments of the invention the nucleic acid sequence is capable of increasing nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant.

According to some embodiments of the invention the isolated polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs:1-467, and 785-3047.

According to some embodiments of the invention the isolated polynucleotide is set forth by SEQ ID NO:1-467, 785-3046 or 3047.

The invention provides an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous to the amino acid sequence selected from the group consisting of SEQ ID NO:468-784, 3048-4333, and 4335-4682.

According to some embodiments of the invention the amino acid sequence is capable of increasing nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant.

The invention provides an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises the amino acid sequence selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, 4335-4682 and 4334.

The invention provides an isolated polypeptide comprising an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous to an amino acid sequence selected from the group consisting of SEQ ID NO: 468-784, 3048-4333, and 4335-4682.

According to some embodiments of the invention, the polypeptide comprising an amino acid sequence selected from the group consisting of SEQ ID NOs:468-784, 3048-4333, 4335-4682 and 4334.

According to some embodiments of the invention, the polypeptide is set forth by SEQ ID NO: 468-784, 3048-4333, 4335-4682 or 4334.

According to some embodiments of the invention, there is provided a nucleic acid construct comprising the isolated polynucleotide of the invention, and a promoter for directing transcription of the nucleic acid sequence of the isolated polynucleotide in a host cell.

The invention also encompasses fragments of the above described polypeptides and polypeptides having mutations, such as deletions, insertions or substitutions of one or more amino acids, either naturally occurring or man induced, either randomly or in a targeted fashion.

The term “plant” as used herein encompasses whole plants, ancestors and progeny of the plants and plant parts, including seeds, shoots, stems, roots (including tubers), and plant cells, tissues and organs. The plant may be in any form including suspension cultures, embryos, meristematic regions, callus tissue, leaves, gametophytes, sporophytes, pollen, and microspores. Plants that are particularly useful in the methods of the invention include all plants which belong to the superfamily Viridiplantae, in particular monocotyledonous and dicotyledonous plants including a fodder or forage legume, ornamental plant, food crop, tree, or shrub selected from the list comprising Acacia spp., Acer spp., Actinidia spp., Aesculus spp., Agathis australis, Albizia amara, Alsophila tricolor, Andropogon spp., Arachis spp, Areca catechu, Astelia fragrans, Astragalus cicer, Baikiaea plurijuga, Betula spp., Brassica spp., Bruguiera gymnorrhiza, Burkea africana, Butea frondosa, Cadaba farinosa, Calliandra spp, Camellia sinensis, Canna indica, Capsicum spp., Cassia spp., Centroema pubescens, Chacoomeles spp., Cinnamomum cassia, Coffea arabica, Colophospermum mopane, Coronillia varia, Cotoneaster serotina, Crataegus spp., Cucumis spp., Cupressus spp., Cyathea dealbata, Cydonia oblonga, Cryptomeria japonica, Cymbopogon spp., Cynthea dealbata, Cydonia oblonga, Dalbergia monetaria, Davallia divaricata, Desmodium spp., Dicksonia squarosa, Dibeteropogon amplectens, Dioclea spp, Dolichos spp., Dorycnium rectum, Echinochloa pyramidalis, Ehraffia spp., Eleusine coracana, Eragrestis spp., Erythrina spp., Eucalypfus spp., Euclea schimperi, Eulalia vi/losa, Pagopyrum spp., Feijoa sellowlana, Fragaria spp., Flemingia spp, Freycinetia banksli, Geranium thunbergii, GinAgo biloba, Glycine javanica, Gliricidia spp, Gossypium hirsutum, Grevillea spp., Guibourtia coleosperma, Hedysarum spp., Hemaffhia altissima, Heteropogon contoffus, Hordeum vulgare, Hyparrhenia rufa, Hypericum erectum, Hypeffhelia dissolute, Indigo incamata, Iris spp., Leptarrhena pyrolifolia, Lespediza spp., Lettuca spp., Leucaena leucocephala, Loudetia simplex, Lotonus bainesli, Lotus spp., Macrotyloma axillare, Malus spp., Manihot esculenta, Medicago saliva, Metasequoia glyptostroboides, Musa sapientum, Nicotianum spp., Onobrychis spp., Ornithopus spp., Oryza spp., Peltophorum africanum, Pennisetum spp., Persea gratissima, Petunia spp., Phaseolus spp., Phoenix canariensis, Phormium cookianum, Photinia spp., Picea glauca, Pinus spp., Pisum sativam, Podocarpus totara, Pogonarthria fleckii, Pogonaffhria squarrosa, Populus spp., Prosopis cineraria, Pseudotsuga menziesii, Pterolobium stellatum, Pyrus communis, Quercus spp., Rhaphiolepsis umbellata, Rhopalostylis sapida, Rhus natalensis, Ribes grossularia, Ribes spp., Robinia pseudoacacia, Rosa spp., Rubus spp., Salix spp., Schyzachyrium sanguineum, Sciadopitys vefficillata, Sequoia sempervirens, Sequoiadendron giganteum, Sorghum bicolor, Spinacia spp., Sporobolus fimbriatus, Stiburus alopecuroides, Stylosanthos humilis, Tadehagi spp, Taxodium distichum, Themeda triandra, Trifolium spp., Triticum spp., Tsuga heterophylla, Vaccinium spp., Vicia spp., Vitis vinifera, Watsonia pyramidata, Zantedeschia aethiopica, Zea mays, amaranth, artichoke, asparagus, broccoli, Brussels sprouts, cabbage, canola, carrot, cauliflower, celery, collard greens, flax, kale, lentil, oilseed rape, okra, onion, potato, rice, soybean, straw, sugar beet, sugar cane, sunflower, tomato, squash tea, maize, wheat, barely, rye, oat, peanut, pea, lentil and alfalfa, cotton, rapeseed, canola, pepper, sunflower, tobacco, eggplant, eucalyptus, a tree, an ornamental plant, a perennial grass and a forage crop. Alternatively algae and other non-Viridiplantae can be used for the methods of the present invention.

According to some embodiments of the invention, the plant used by the method of the invention is a crop plant such as rice, maize, wheat, barley, peanut, potato, sesame, olive tree, palm oil, banana, soybean, sunflower, canola, sugarcane, alfalfa, millet, leguminosae (bean, pea), flax, lupinus, rapeseed, tobacco, poplar and cotton.

According to some embodiments of the invention, there is provided a plant cell exogenously expressing the polynucleotide of some embodiments of the invention, the nucleic acid construct of some embodiments of the invention and/or the polypeptide of some embodiments of the invention.

According to some embodiments of the invention, expressing the exogenous polynucleotide of the invention within the plant is effected by transforming one or more cells of the plant with the exogenous polynucleotide, followed by generating a mature plant from the transformed cells and cultivating the mature plant under conditions suitable for expressing the exogenous polynucleotide within the mature plant.

According to some embodiments of the invention, the transformation is effected by introducing to the plant cell a nucleic acid construct which includes the exogenous polynucleotide of some embodiments of the invention and at least one promoter for directing transcription of the exogenous polynucleotide in a host cell (a plant cell). Further details of suitable transformation approaches are provided hereinbelow.

As mentioned, the nucleic acid construct according to some embodiments of the invention comprises a promoter sequence and the isolated polynucleotide of the invention.

According to some embodiments of the invention, the isolated polynucleotide is operably linked to the promoter sequence.

A coding nucleic acid sequence is “operably linked” to a regulatory sequence (e.g., promoter) if the regulatory sequence is capable of exerting a regulatory effect on the coding sequence linked thereto.

As used herein, the term “promoter” refers to a region of DNA which lies upstream of the transcriptional initiation site of a gene to which RNA polymerase binds to initiate transcription of RNA. The promoter controls where (e.g., which portion of a plant) and/or when (e.g., at which stage or condition in the lifetime of an organism) the gene is expressed.

According to some embodiments of the invention the promoter is heterologous to the isolated polynucleotide (e.g., derived from another gene or species with respect to the isolated polynucleotide).

According to some embodiments of the invention the promoter is heterologous to the host cell (e.g., derived from another cell type, or species with respect to the host cell).

According to some embodiments of the invention the promoter is heterologous to the isolated polynucleotide and to the host cell.

Any suitable promoter sequence can be used by the nucleic acid construct of the present invention. Preferably the promoter is a constitutive promoter, a tissue-specific, or an abiotic stress-inducible promoter.

Suitable constitutive promoters include, for example, CaMV 35S promoter (SEQ ID NO:4685; Odell et al., Nature 313:810-812, 1985); Arabidopsis At6669 promoter (SEQ ID NO:4684; see PCT Publication No. WO04081173A2); Arabidopsis new At6669 promoter (SEQ ID NO:4687); maize Ubi 1 (Christensen et al., Plant Sol. Biol. 18:675-689, 1992); rice actin (McElroy et al., Plant Cell 2:163-171, 1990); pEMU (Last et al., Theor. Appl. Genet. 81:581-588, 1991); CaMV 19S (Nilsson et al., Physiol. Plant 100:456-462, 1997); GOS2 (de Pater et al, Plant J November; 2(6):837-44, 1992); ubiquitin (Christensen et al, Plant Mol. Biol. 18: 675-689, 1992); Rice cyclophilin (Bucholz et al, Plant Mol Biol. 25(5):837-43, 1994); Maize H3 histone (Lepetit et al, Mol. Gen. Genet. 231: 276-285, 1992); Actin 2 (An et al, Plant J. 10(1); 107-121, 1996) and Synthetic Super MAS (Ni et al., The Plant Journal 7: 661-76, 1995). Other constitutive promoters include those in U.S. Pat. Nos. 5,659,026, 5,608,149; 5,608,144; 5,604,121; 5,569,597; 5,466,785; 5,399,680; 5,268,463; and 5,608,142.

Suitable tissue-specific promoters include, but not limited to, leaf-specific promoters [such as described, for example, by Yamamoto et al., Plant J. 12:255-265, 1997; Kwon et al., Plant Physiol. 105:357-67, 1994; Yamamoto et al., Plant Cell Physiol. 35:773-778, 1994; Gotor et al., Plant J. 3:509-18, 1993; Orozco et al., Plant Mol. Biol. 23:1129-1138, 1993; and Matsuoka et al., Proc. Natl. Acad. Sci. USA 90:9586-9590, 1993], seed-preferred promoters [e.g., Napin (originated from Brassica napus which is characterized by a seed specific promoter activity; Stuitje A. R. et. al. Plant Biotechnology Journal 1 (4): 301-309; SEQ ID NO:4686), from seed specific genes (Simon, et al., Plant Mol. Biol. 5. 191, 1985; Scofield, et al., J. Biol. Chem. 262: 12202, 1987; Baszczynski, et al., Plant Mol. Biol. 14: 633, 1990), Brazil Nut albumin (Pearson' et al., Plant Mol. Biol. 18: 235-245, 1992), legumin (Ellis, et al. Plant Mol. Biol. 10: 203-214, 1988), Glutelin (rice) (Takaiwa, et al., Mol. Gen. Genet. 208: 15-22, 1986; Takaiwa, et al., FEBS Letts. 221: 43-47, 1987), Zein (Matzke et al Plant Mol Biol, 143). 323-32 1990), napA (Stalberg, et al, Planta 199: 515-519, 1996), Wheat SPA (Albanietal, Plant Cell, 9: 171-184, 1997), sunflower oleosin (Cummins, et al., Plant Mol. Biol. 19: 873-876, 1992)], endosperm specific promoters [e.g., wheat LMW and HMW, glutenin-1 (Mol Gen Genet 216:81-90, 1989; NAR 17:461-2), wheat a, b and g gliadins (EMBO3:1409-15, 1984), Barley ltrl promoter, barley B1, C, D hordein (Theor Appl Gen 98:1253-62, 1999; Plant J 4:343-55, 1993; Mol Gen Genet 250:750-60, 1996), Barley DOF (Mena et al, The Plant Journal, 116(1): 53-62, 1998), Biz2 (EP99106056.7), Synthetic promoter (Vicente-Carbajosa et al., Plant J. 13: 629-640, 1998), rice prolamin NRP33, rice-globulin Glb-1 (Wu et al, Plant Cell Physiology 39(8) 885-889, 1998), rice alpha-globulin REB/OHP-1 (Nakase et al. Plant Mol. Biol. 33: 513-S22, 1997), rice ADP-glucose PP (Trans Res 6:157-68, 1997), maize ESR gene family (Plant J 12:235-46, 1997), sorgum gamma-kafirin (PMB 32:1029-35, 1996)], embryo specific promoters [e.g., rice OSH1 (Sato et al, Proc. Nati. Acad. Sci. USA, 93: 8117-8122), KNOX (Postma-Haarsma et al, Plant Mol. Biol. 39:257-71, 1999), rice oleosin (Wu et at, J. Biochem., 123:386, 1998)], and flower-specific promoters [e.g., AtPRP4, chalene synthase (chsA) (Van der Meer, et al., Plant Mol. Biol. 15, 95-109, 1990), LAT52 (Twell et al Mol. Gen Genet. 217:240-245; 1989), apetala-3], and root promoters such as the RootP promoter [SEQ ID NO:4688; Upstream region of the gene ATXTH19 (AT4G30290, Xyloglucan endotransglucosylase/hydrolase 19, described in Vissenberg K, et al. Plant Cell Physiol. 2005 January; 46(1):192-200].

Suitable abiotic stress-inducible promoters include, but not limited to, salt-inducible promoters such as RD29A (Yamaguchi-Shinozalei et al., Mol. Gen. Genet. 236:331-340, 1993); drought-inducible promoters such as maize rab17 gene promoter (Pla et. al., Plant Mol. Biol. 21:259-266, 1993), maize rab28 gene promoter (Busk et. al., Plant J. 11:1285-1295, 1997) and maize Ivr2 gene promoter (Pelleschi et. al., Plant Mol. Biol. 39:373-380, 1999); heat-inducible promoters such as heat tomato hsp80-promoter from tomato (U.S. Pat. No. 5,187,267).

The nucleic acid construct of some embodiments of the invention can further include an appropriate selectable marker and/or an origin of replication. According to some embodiments of the invention, the nucleic acid construct utilized is a shuttle vector, which can propagate both in E. coli (wherein the construct comprises an appropriate selectable marker and origin of replication) and be compatible with propagation in cells. The construct according to the present invention can be, for example, a plasmid, a bacmid, a phagemid, a cosmid, a phage, a virus or an artificial chromosome.

The nucleic acid construct of some embodiments of the invention can be utilized to stably or transiently transform plant cells. In stable transformation, the exogenous polynucleotide is integrated into the plant genome and as such it represents a stable and inherited trait. In transient transformation, the exogenous polynucleotide is expressed by the cell transformed but it is not integrated into the genome and as such it represents a transient trait.

There are various methods of introducing foreign genes into both monocotyledonous and dicotyledonous plants (Potrykus, I., Annu. Rev. Plant. Physiol., Plant. Mol. Biol. (1991) 42:205-225; Shimamoto et al., Nature (1989) 338:274-276).

The principle methods of causing stable integration of exogenous DNA into plant genomic DNA include two main approaches:

(i) Agrobacterium-mediated gene transfer: Klee et al. (1987) Annu. Rev. Plant Physiol. 38:467-486; Klee and Rogers in Cell Culture and Somatic Cell Genetics of Plants, Vol. 6, Molecular Biology of Plant Nuclear Genes, eds. Schell, J., and Vasil, L. K., Academic Publishers, San Diego, Calif. (1989) p. 2-25; Gatenby, in Plant Biotechnology, eds. Kung, S. and Arntzen, C. J., Butterworth Publishers, Boston, Mass. (1989) p. 93-112.

(ii) Direct DNA uptake: Paszkowski et al., in Cell Culture and Somatic Cell Genetics of Plants, Vol. 6, Molecular Biology of Plant Nuclear Genes eds. Schell, J., and Vasil, L. K., Academic Publishers, San Diego, Calif. (1989) p. 52-68; including methods for direct uptake of DNA into protoplasts, Toriyama, K. et al. (1988) Bio/Technology 6:1072-1074. DNA uptake induced by brief electric shock of plant cells: Zhang et al. Plant Cell Rep. (1988) 7:379-384. Fromm et al. Nature (1986) 319:791-793. DNA injection into plant cells or tissues by particle bombardment, Klein et al. Bio/Technology (1988) 6:559-563; McCabe et al. Bio/Technology (1988) 6:923-926; Sanford, Physiol. Plant. (1990) 79:206-209; by the use of micropipette systems: Neuhaus et al., Theor. Appl. Genet. (1987) 75:30-36; Neuhaus and Spangenberg, Physiol. Plant. (1990) 79:213-217; glass fibers or silicon carbide whisker transformation of cell cultures, embryos or callus tissue, U.S. Pat. No. 5,464,765 or by the direct incubation of DNA with germinating pollen, DeWet et al. in Experimental Manipulation of Ovule Tissue, eds. Chapman, G. P. and Mantell, S. H. and Daniels, W. Longman, London, (1985) p. 197-209; and Ohta, Proc. Natl. Acad. Sci. USA (1986) 83:715-719.

The Agrobacterium system includes the use of plasmid vectors that contain defined DNA segments that integrate into the plant genomic DNA. Methods of inoculation of the plant tissue vary depending upon the plant species and the Agrobacterium delivery system. A widely used approach is the leaf disc procedure which can be performed with any tissue explant that provides a good source for initiation of whole plant differentiation. See, e.g., Horsch et al. in Plant Molecular Biology Manual A5, Kluwer Academic Publishers, Dordrecht (1988) p. 1-9. A supplementary approach employs the Agrobacterium delivery system in combination with vacuum infiltration. The Agrobacterium system is especially viable in the creation of transgenic dicotyledonous plants.

There are various methods of direct DNA transfer into plant cells. In electroporation, the protoplasts are briefly exposed to a strong electric field. In microinjection, the DNA is mechanically injected directly into the cells using very small micropipettes. In microparticle bombardment, the DNA is adsorbed on microprojectiles such as magnesium sulfate crystals or tungsten particles, and the microprojectiles are physically accelerated into cells or plant tissues.

Following stable transformation plant propagation is exercised. The most common method of plant propagation is by seed. Regeneration by seed propagation, however, has the deficiency that due to heterozygosity there is a lack of uniformity in the crop, since seeds are produced by plants according to the genetic variances governed by Mendelian rules. Basically, each seed is genetically different and each will grow with its own specific traits. Therefore, it is preferred that the transformed plant be produced such that the regenerated plant has the identical traits and characteristics of the parent transgenic plant. Therefore, it is preferred that the transformed plant be regenerated by micropropagation which provides a rapid, consistent reproduction of the transformed plants.

Micropropagation is a process of growing new generation plants from a single piece of tissue that has been excised from a selected parent plant or cultivar. This process permits the mass reproduction of plants having the preferred tissue expressing the fusion protein. The new generation plants which are produced are genetically identical to, and have all of the characteristics of, the original plant. Micropropagation allows mass production of quality plant material in a short period of time and offers a rapid multiplication of selected cultivars in the preservation of the characteristics of the original transgenic or transformed plant. The advantages of cloning plants are the speed of plant multiplication and the quality and uniformity of plants produced.

Micropropagation is a multi-stage procedure that requires alteration of culture medium or growth conditions between stages. Thus, the micropropagation process involves four basic stages: Stage one, initial tissue culturing; stage two, tissue culture multiplication; stage three, differentiation and plant formation; and stage four, greenhouse culturing and hardening. During stage one, initial tissue culturing, the tissue culture is established and certified contaminant-free. During stage two, the initial tissue culture is multiplied until a sufficient number of tissue samples are produced to meet production goals. During stage three, the tissue samples grown in stage two are divided and grown into individual plantlets. At stage four, the transformed plantlets are transferred to a greenhouse for hardening where the plants' tolerance to light is gradually increased so that it can be grown in the natural environment.

According to some embodiments of the invention, the transgenic plants are generated by transient transformation of leaf cells, meristematic cells or the whole plant.

Transient transformation can be effected by any of the direct DNA transfer methods described above or by viral infection using modified plant viruses.

Viruses that have been shown to be useful for the transformation of plant hosts include CaMV, Tobacco mosaic virus (TMV), brome mosaic virus (BMV) and Bean Common Mosaic Virus (BV or BCMV). Transformation of plants using plant viruses is described in U.S. Pat. No. 4,855,237 (bean golden mosaic virus; BGV), EP-A 67,553 (TMV), Japanese Published Application No. 63-14693 (TMV), EPA 194,809 (BV), EPA 278,667 (BV); and Gluzman, Y. et al., Communications in Molecular Biology: Viral Vectors, Cold Spring Harbor Laboratory, New York, pp. 172-189 (1988). Pseudovirus particles for use in expressing foreign DNA in many hosts, including plants are described in WO 87/06261.

According to some embodiments of the invention, the virus used for transient transformations is avirulent and thus is incapable of causing severe symptoms such as reduced growth rate, mosaic, ring spots, leaf roll, yellowing, streaking, pox formation, tumor formation and pitting. A suitable avirulent virus may be a naturally occurring avirulent virus or an artificially attenuated virus. Virus attenuation may be effected by using methods well known in the art including, but not limited to, sub-lethal heating, chemical treatment or by directed mutagenesis techniques such as described, for example, by Kurihara and Watanabe (Molecular Plant Pathology 4:259-269, 2003), Gal-on et al. (1992), Atreya et al. (1992) and Huet et al. (1994).

Suitable virus strains can be obtained from available sources such as, for example, the American Type culture Collection (ATCC) or by isolation from infected plants. Isolation of viruses from infected plant tissues can be effected by techniques well known in the art such as described, for example by Foster and Tatlor, Eds. “Plant Virology Protocols: From Virus Isolation to Transgenic Resistance (Methods in Molecular Biology (Humana Pr), Vol 81)”, Humana Press, 1998. Briefly, tissues of an infected plant believed to contain a high concentration of a suitable virus, preferably young leaves and flower petals, are ground in a buffer solution (e.g., phosphate buffer solution) to produce a virus infected sap which can be used in subsequent inoculations.

Construction of plant RNA viruses for the introduction and expression of non-viral exogenous polynucleotide sequences in plants is demonstrated by the above references as well as by Dawson, W. O. et al., Virology (1989) 172:285-292; Takamatsu et al. EMBO J. (1987) 6:307-311; French et al. Science (1986) 231:1294-1297; Takamatsu et al. FEBS Letters (1990) 269:73-76; and U.S. Pat. No. 5,316,931.

When the virus is a DNA virus, suitable modifications can be made to the virus itself. Alternatively, the virus can first be cloned into a bacterial plasmid for ease of constructing the desired viral vector with the foreign DNA. The virus can then be excised from the plasmid. If the virus is a DNA virus, a bacterial origin of replication can be attached to the viral DNA, which is then replicated by the bacteria. Transcription and translation of this DNA will produce the coat protein which will encapsidate the viral DNA. If the virus is an RNA virus, the virus is generally cloned as a cDNA and inserted into a plasmid. The plasmid is then used to make all of the constructions. The RNA virus is then produced by transcribing the viral sequence of the plasmid and translation of the viral genes to produce the coat protein(s) which encapsidate the viral RNA.

In one embodiment, a plant viral polynucleotide is provided in which the native coat protein coding sequence has been deleted from a viral polynucleotide, a non-native plant viral coat protein coding sequence and a non-native promoter, preferably the subgenomic promoter of the non-native coat protein coding sequence, capable of expression in the plant host, packaging of the recombinant plant viral polynucleotide, and ensuring a systemic infection of the host by the recombinant plant viral polynucleotide, has been inserted. Alternatively, the coat protein gene may be inactivated by insertion of the non-native polynucleotide sequence within it, such that a protein is produced. The recombinant plant viral polynucleotide may contain one or more additional non-native subgenomic promoters. Each non-native subgenomic promoter is capable of transcribing or expressing adjacent genes or polynucleotide sequences in the plant host and incapable of recombination with each other and with native subgenomic promoters. Non-native (foreign) polynucleotide sequences may be inserted adjacent the native plant viral subgenomic promoter or the native and a non-native plant viral subgenomic promoters if more than one polynucleotide sequence is included. The non-native polynucleotide sequences are transcribed or expressed in the host plant under control of the subgenomic promoter to produce the desired products.

In a second embodiment, a recombinant plant viral polynucleotide is provided as in the first embodiment except that the native coat protein coding sequence is placed adjacent one of the non-native coat protein subgenomic promoters instead of a non-native coat protein coding sequence.

In a third embodiment, a recombinant plant viral polynucleotide is provided in which the native coat protein gene is adjacent its subgenomic promoter and one or more non-native subgenomic promoters have been inserted into the viral polynucleotide. The inserted non-native subgenomic promoters are capable of transcribing or expressing adjacent genes in a plant host and are incapable of recombination with each other and with native subgenomic promoters. Non-native polynucleotide sequences may be inserted adjacent the non-native subgenomic plant viral promoters such that the sequences are transcribed or expressed in the host plant under control of the subgenomic promoters to produce the desired product.

In a fourth embodiment, a recombinant plant viral polynucleotide is provided as in the third embodiment except that the native coat protein coding sequence is replaced by a non-native coat protein coding sequence.

The viral vectors are encapsidated by the coat proteins encoded by the recombinant plant viral polynucleotide to produce a recombinant plant virus. The recombinant plant viral polynucleotide or recombinant plant virus is used to infect appropriate host plants. The recombinant plant viral polynucleotide is capable of replication in the host, systemic spread in the host, and transcription or expression of foreign gene(s) (exogenous polynucleotide) in the host to produce the desired protein.

Techniques for inoculation of viruses to plants may be found in Foster and Taylor, eds. “Plant Virology Protocols: From Virus Isolation to Transgenic Resistance (Methods in Molecular Biology (Humana Pr), Vol 81)”, Humana Press, 1998; Maramorosh and Koprowski, eds. “Methods in Virology” 7 vols, Academic Press, New York 1967-1984; Hill, S. A. “Methods in Plant Virology”, Blackwell, Oxford, 1984; Walkey, D. G. A. “Applied Plant Virology”, Wiley, New York, 1985; and Kado and Agrawa, eds. “Principles and Techniques in Plant Virology”, Van Nostrand-Reinhold, New York.

In addition to the above, the polynucleotide of the present invention can also be introduced into a chloroplast genome thereby enabling chloroplast expression.

A technique for introducing exogenous polynucleotide sequences to the genome of the chloroplasts is known. This technique involves the following procedures. First, plant cells are chemically treated so as to reduce the number of chloroplasts per cell to about one. Then, the exogenous polynucleotide is introduced via particle bombardment into the cells with the aim of introducing at least one exogenous polynucleotide molecule into the chloroplasts. The exogenous polynucleotides selected such that it is integratable into the chloroplast's genome via homologous recombination which is readily effected by enzymes inherent to the chloroplast. To this end, the exogenous polynucleotide includes, in addition to a gene of interest, at least one polynucleotide stretch which is derived from the chloroplast's genome. In addition, the exogenous polynucleotide includes a selectable marker, which serves by sequential selection procedures to ascertain that all or substantially all of the copies of the chloroplast genomes following such selection will include the exogenous polynucleotide. Further details relating to this technique are found in U.S. Pat. Nos. 4,945,050; and 5,693,507 which are incorporated herein by reference. A polypeptide can thus be produced by the protein expression system of the chloroplast and become integrated into the chloroplast's inner membrane.

Since processes which increase nitrogen use efficiency, fertilizer use efficiency, oil content, yield, seed yield, fiber yield, fiber quality, fiber length, growth rate, biomass, vigor and/or abiotic stress tolerance of a plant can involve multiple genes acting additively or in synergy (see, for example, in Quesda et al., Plant Physiol. 130:951-063, 2002), the present invention also envisages expressing a plurality of exogenous polynucleotides in a single host plant to thereby achieve superior effect on oil content, yield, growth rate, biomass, vigor and/or abiotic stress tolerance.

Expressing a plurality of exogenous polynucleotides in a single host plant can be effected by co-introducing multiple nucleic acid constructs, each including a different exogenous polynucleotide, into a single plant cell. The transformed cell can than be regenerated into a mature plant using the methods described hereinabove.

Alternatively, expressing a plurality of exogenous polynucleotides in a single host plant can be effected by co-introducing into a single plant-cell a single nucleic-acid construct including a plurality of different exogenous polynucleotides. Such a construct can be designed with a single promoter sequence which can transcribe a polycistronic messenger RNA including all the different exogenous polynucleotide sequences. To enable co-translation of the different polypeptides encoded by the polycistronic messenger RNA, the polynucleotide sequences can be inter-linked via an internal ribosome entry site (IRES) sequence which facilitates translation of polynucleotide sequences positioned downstream of the IRES sequence. In this case, a transcribed polycistronic RNA molecule encoding the different polypeptides described above will be translated from both the capped 5′ end and the two internal IRES sequences of the polycistronic RNA molecule to thereby produce in the cell all different polypeptides. Alternatively, the construct can include several promoter sequences each linked to a different exogenous polynucleotide sequence.

The plant cell transformed with the construct including a plurality of different exogenous polynucleotides, can be regenerated into a mature plant, using the methods described hereinabove.

Alternatively, expressing a plurality of exogenous polynucleotides in a single host plant can be effected by introducing different nucleic acid constructs, including different exogenous polynucleotides, into a plurality of plants. The regenerated transformed plants can then be cross-bred and resultant progeny selected for superior abiotic stress tolerance, water use efficiency, fertilizer use efficiency, growth, biomass, yield and/or vigor traits, using conventional plant breeding techniques.

According to some embodiments of the invention, the method further comprising growing the plant expressing the exogenous polynucleotide under the abiotic stress.

Non-limiting examples of abiotic stress conditions include, salinity, drought, water deprivation, excess of water (e.g., flood, waterlogging), etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nutrient excess, atmospheric pollution and UV irradiation.

Thus, the invention encompasses plants exogenously expressing the polynucleotide(s), the nucleic acid constructs and/or polypeptide(s) of the invention. Once expressed within the plant cell or the entire plant, the level of the polypeptide encoded by the exogenous polynucleotide can be determined by methods well known in the art such as, activity assays, Western blots using antibodies capable of specifically binding the polypeptide, Enzyme-Linked Immuno Sorbent Assay (ELISA), radio-immuno-assays (RIA), immunohistochemistry, immunocytochemistry, immunofluorescence and the like.

Methods of determining the level in the plant of the RNA transcribed from the exogenous polynucleotide are well known in the art and include, for example, Northern blot analysis, reverse transcription polymerase chain reaction (RT-PCR) analysis (including quantitative, semi-quantitative or real-time RT-PCR) and RNA-in situ hybridization.

The sequence information and annotations uncovered by the present teachings can be harnessed in favor of classical breeding. Thus, sub-sequence data of those polynucleotides described above, can be used as markers for marker assisted selection (MAS), in which a marker is used for indirect selection of a genetic determinant or determinants of a trait of interest (e.g., biomass, growth rate, oil content, yield, abiotic stress tolerance, water use efficiency, nitrogen use efficiency and/or fertilizer use efficiency). Nucleic acid data of the present teachings (DNA or RNA sequence) may contain or be linked to polymorphic sites or genetic markers on the genome such as restriction fragment length polymorphism (RFLP), microsatellites and single nucleotide polymorphism (SNP), DNA fingerprinting (DFP), amplified fragment length polymorphism (AFLP), expression level polymorphism, polymorphism of the encoded polypeptide and any other polymorphism at the DNA or RNA sequence.

Examples of marker assisted selections include, but are not limited to, selection for a morphological trait (e.g., a gene that affects form, coloration, male sterility or resistance such as the presence or absence of awn, leaf sheath coloration, height, grain color, aroma of rice); selection for a biochemical trait (e.g., a gene that encodes a protein that can be extracted and observed; for example, isozymes and storage proteins); selection for a biological trait (e.g., pathogen races or insect biotypes based on host pathogen or host parasite interaction can be used as a marker since the genetic constitution of an organism can affect its susceptibility to pathogens or parasites).

The polynucleotides and polypeptides described hereinabove can be used in a wide range of economical plants, in a safe and cost effective manner.

Plant lines exogenously expressing the polynucleotide or the polypeptide of the invention are screened to identify those that show the greatest increase of the desired plant trait.

The effect of the transgene (the exogenous polynucleotide encoding the polypeptide) on abiotic stress tolerance can be determined using known methods such as detailed below and in the Examples section which follows.

Abiotic stress tolerance—Transformed (i.e., expressing the transgene) and non-transformed (wild type) plants are exposed to an abiotic stress condition, such as water deprivation, suboptimal temperature (low temperature, high temperature), nutrient deficiency, nutrient excess, a salt stress condition, osmotic stress, heavy metal toxicity, anaerobiosis, atmospheric pollution and UV irradiation.

Salinity tolerance assay—Transgenic plants with tolerance to high salt concentrations are expected to exhibit better germination, seedling vigor or growth in high salt. Salt stress can be effected in many ways such as, for example, by irrigating the plants with a hyperosmotic solution, by cultivating the plants hydroponically in a hyperosmotic growth solution (e.g., Hoagland solution), or by culturing the plants in a hyperosmotic growth medium [e.g., 50% Murashige-Skoog medium (MS medium)]. Since different plants vary considerably in their tolerance to salinity, the salt concentration in the irrigation water, growth solution, or growth medium can be adjusted according to the specific characteristics of the specific plant cultivar or variety, so as to inflict a mild or moderate effect on the physiology and/or morphology of the plants (for guidelines as to appropriate concentration see, Bernstein and Kafkafi, Root Growth Under Salinity Stress In: Plant Roots, The Hidden Half 3rd ed. Waisel Y, Eshel A and Kafkafi U. (editors) Marcel Dekker Inc., New York, 2002, and reference therein).

For example, a salinity tolerance test can be performed by irrigating plants at different developmental stages with increasing concentrations of sodium chloride (for example 50 mM, 100 mM, 200 mM, 400 mM NaCl) applied from the bottom and from above to ensure even dispersal of salt. Following exposure to the stress condition the plants are frequently monitored until substantial physiological and/or morphological effects appear in wild type plants. Thus, the external phenotypic appearance, degree of wilting and overall success to reach maturity and yield progeny are compared between control and transgenic plants.

Quantitative parameters of tolerance measured include, but are not limited to, the average wet and dry weight, growth rate, leaf size, leaf coverage (overall leaf area), the weight of the seeds yielded, the average seed size and the number of seeds produced per plant. Transformed plants not exhibiting substantial physiological and/or morphological effects, or exhibiting higher biomass than wild-type plants, are identified as abiotic stress tolerant plants.

Osmotic tolerance test—Osmotic stress assays (including sodium chloride and mannitol assays) are conducted to determine if an osmotic stress phenotype was sodium chloride-specific or if it was a general osmotic stress related phenotype. Plants which are tolerant to osmotic stress may have more tolerance to drought and/or freezing. For salt and osmotic stress germination experiments, the medium is supplemented for example with 50 mM, 100 mM, 200 mM NaCl or 100 mM, 200 mM NaCl, 400 mM mannitol.

Drought tolerance assay/Osmoticum assay—Tolerance to drought is performed to identify the genes conferring better plant survival after acute water deprivation. To analyze whether the transgenic plants are more tolerant to drought, an osmotic stress produced by the non-ionic osmolyte sorbitol in the medium can be performed. Control and transgenic plants are germinated and grown in plant-agar plates for 4 days, after which they are transferred to plates containing 500 mM sorbitol. The treatment causes growth retardation, then both control and transgenic plants are compared, by measuring plant weight (wet and dry), yield, and by growth rates measured as time to flowering.

Conversely, soil-based drought screens are performed with plants overexpressing the polynucleotides detailed above. Seeds from control Arabidopsis plants, or other transgenic plants overexpressing the polypeptide of the invention are germinated and transferred to pots. Drought stress is obtained after irrigation is ceased accompanied by placing the pots on absorbent paper to enhance the soil-drying rate. Transgenic and control plants are compared to each other when the majority of the control plants develop severe wilting. Plants are re-watered after obtaining a significant fraction of the control plants displaying a severe wilting. Plants are ranked comparing to controls for each of two criteria: tolerance to the drought conditions and recovery (survival) following re-watering.

Cold stress tolerance—To analyze cold stress, mature (25 day old) plants are transferred to 4° C. chambers for 1 or 2 weeks, with constitutive light. Later on plants are moved back to greenhouse. Two weeks later damages from chilling period, resulting in growth retardation and other phenotypes, are compared between both control and transgenic plants, by measuring plant weight (wet and dry), and by comparing growth rates measured as time to flowering, plant size, yield, and the like.

Heat stress tolerance—Heat stress tolerance is achieved by exposing the plants to temperatures above 34° C. for a certain period. Plant tolerance is examined after transferring the plants back to 22° C. for recovery and evaluation after 5 days relative to internal controls (non-transgenic plants) or plants not exposed to neither cold or heat stress.

Water use efficiency—can be determined as the biomass produced per unit transpiration. To analyze WUE, leaf relative water content can be measured in control and transgenic plants. Fresh weight (FW) is immediately recorded; then leaves are soaked for 8 hours in distilled water at room temperature in the dark, and the turgid weight (TW) is recorded. Total dry weight (DW) is recorded after drying the leaves at 60° C. to a constant weight. Relative water content (RWC) is calculated according to the following Formula I:

RWC=[(FW−DW)/(TW−DW)]×100  Formula I

Fertilizer use efficiency—To analyze whether the transgenic plants are more responsive to fertilizers, plants are grown in agar plates or pots with a limited amount of fertilizer, as described, for example, in Examples 14, 15 and 16, hereinbelow and in Yanagisawa et al (Proc Natl Acad Sci USA. 2004; 101:7833-8). The plants are analyzed for their overall size, time to flowering, yield, protein content of shoot and/or grain. The parameters checked are the overall size of the mature plant, its wet and dry weight, the weight of the seeds yielded, the average seed size and the number of seeds produced per plant. Other parameters that may be tested are: the chlorophyll content of leaves (as nitrogen plant status and the degree of leaf verdure is highly correlated), amino acid and the total protein content of the seeds or other plant parts such as leaves or shoots, oil content, etc. Similarly, instead of providing nitrogen at limiting amounts, phosphate or potassium can be added at increasing concentrations. Again, the same parameters measured are the same as listed above. In this way, nitrogen use efficiency (NUE), phosphate use efficiency (PUE) and potassium use efficiency (KUE) are assessed, checking the ability of the transgenic plants to thrive under nutrient restraining conditions.

Nitrogen use efficiency—To analyze whether the transgenic plants (e.g., Arabidopsis plants) are more responsive to nitrogen, plant are grown in 0.75-3 mM (nitrogen deficient conditions) or 6-10 mM (optimal nitrogen concentration). Plants are allowed to grow for additional 25 days or until seed production. The plants are then analyzed for their overall size, time to flowering, yield, protein content of shoot and/or grain/seed production. The parameters checked can be the overall size of the plant, wet and dry weight, the weight of the seeds yielded, the average seed size and the number of seeds produced per plant. Other parameters that may be tested are: the chlorophyll content of leaves (as nitrogen plant status and the degree of leaf greenness is highly correlated), amino acid and the total protein content of the seeds or other plant parts such as leaves or shoots and oil content. Transformed plants not exhibiting substantial physiological and/or morphological effects, or exhibiting higher measured parameters levels than wild-type plants, are identified as nitrogen use efficient plants.

Nitrogen use efficiency assay using plantlets—The assay is done according to Yanagisawa-S. et al. with minor modifications (“Metabolic engineering with Dof1 transcription factor in plants: Improved nitrogen assimilation and growth under low-nitrogen conditions” Proc. Natl. Acad. Sci. USA 101, 7833-7838). Briefly, transgenic plants which are grown for 7-10 days in 0.5×MS [Murashige-Skoog] supplemented with a selection agent are transferred to two nitrogen-limiting conditions: MS media in which the combined nitrogen concentration (NH₄NO₃ and KNO₃) was 0.75 mM (nitrogen deficient conditions) or 6-15 mM (optimal nitrogen concentration). Plants are allowed to grow for additional 30-40 days and then photographed, individually removed from the Agar (the shoot without the roots) and immediately weighed (fresh weight) for later statistical analysis. Constructs for which only T1 seeds are available are sown on selective media and at least 20 seedlings (each one representing an independent transformation event) are carefully transferred to the nitrogen-limiting media. For constructs for which T2 seeds are available, different transformation events are analyzed. Usually, 20 randomly selected plants from each event are transferred to the nitrogen-limiting media allowed to grow for 3-4 additional weeks and individually weighed at the end of that period. Transgenic plants are compared to control plants grown in parallel under the same conditions. Mock-transgenic plants expressing the uidA reporter gene (GUS) under the same promoter or transgenic plants carrying the same promoter but lacking a reporter gene are used as control.

Nitrogen determination—The procedure for N (nitrogen) concentration determination in the structural parts of the plants involves the potassium persulfate digestion method to convert organic N to NO₃ ⁻ (Purcell and King 1996 Argon. J. 88:111-113, the modified Cd⁻ mediated reduction of NO₃ ⁻ to NO₂ ⁻ (Vodovotz 1996 Biotechniques 20:390-394) and the measurement of nitrite by the Griess assay (Vodovotz 1996, supra). The absorbance values are measured at 550 nm against a standard curve of NaNO₂. The procedure is described in details in Samonte et al. 2006 Agron. J. 98:168-176.

Germination tests—Germination tests compare the percentage of seeds from transgenic plants that could complete the germination process to the percentage of seeds from control plants that are treated in the same manner. Normal conditions are considered for example, incubations at 22° C. under 22-hour light 2-hour dark daily cycles. Evaluation of germination and seedling vigor is conducted between 4 and 14 days after planting. The basal media is 50% MS medium (Murashige and Skoog, 1962 Plant Physiology 15, 473-497).

Germination is checked also at unfavorable conditions such as cold (incubating at temperatures lower than 10° C. instead of 22° C.) or using seed inhibition solutions that contain high concentrations of an osmolyte such as sorbitol (at concentrations of 50 mM, 100 mM, 200 mM, 300 mM, 500 mM, and up to 1000 mM) or applying increasing concentrations of salt (of 50 mM, 100 mM, 200 mM, 300 mM, 500 mM NaCl).

The effect of the transgene on plant's vigor, growth rate, biomass, yield and/or oil content can be determined using known methods.

Plant vigor—The plant vigor can be calculated by the increase in growth parameters such as leaf area, fiber length, rosette diameter, plant fresh weight and the like per time.

Growth rate—The growth rate can be measured using digital analysis of growing plants. For example, images of plants growing in greenhouse on plot basis can be captured every 3 days and the rosette area can be calculated by digital analysis. Rosette area growth is calculated using the difference of rosette area between days of sampling divided by the difference in days between samples.

Evaluation of growth rate can be done by measuring plant biomass produced, rosette area, leaf size or root length per time (can be measured in cm² per day of leaf area).

Relative growth area can be calculated using Formula II.

Relative growth rate area=Regression coefficient of area along time course.  Formula II:

Seed yield—Evaluation of the seed yield per plant can be done by measuring the amount (weight or size) or quantity (i.e., number) of dry seeds produced and harvested from 8-16 plants and divided by the number of plants.

For example, the total seeds from 8-16 plants can be collected, weighted using e.g., an analytical balance and the total weight can be divided by the number of plants. Seed yield per growing area can be calculated in the same manner while taking into account the growing area given to a single plant. Increase seed yield per growing area could be achieved by increasing seed yield per plant, and/or by increasing number of plants capable of growing in a given area.

In addition, seed yield can be determined via the weight of 1000 seeds. The weight of 1000 seeds can be determined as follows: seeds are scattered on a glass tray and a picture is taken. Each sample is weighted and then using the digital analysis, the number of seeds in each sample is calculated.

The 1000 seeds weight can be calculated using formula III:

1000 Seed Weight=number of seed in sample/sample weight×1000  Formula III:

The Harvest Index can be calculated using Formula IV

Harvest Index=Average seed yield per plant/Average dry weight  Formula IV:

Grain protein concentration—Grain protein content (g grain protein m⁻²) is estimated as the product of the mass of grain N (g grain N m⁻²) multiplied by the N/protein conversion ratio of k-5.13 (Mosse 1990, supra). The grain protein concentration is estimated as the ratio of grain protein content per unit mass of the grain (g grain protein kg⁻¹ grain).

Fiber length—Fiber length can be measured using fibrograph. The fibrograph system was used to compute length in terms of “Upper Half Mean” length. The upper half mean (UHM) is the average length of longer half of the fiber distribution. The fibrograph measures length in span lengths at a given percentage point (Hypertext Transfer Protocol://World Wide Web (dot) cottoninc (dot) com/ClassificationofCotton/?Pg=4#Length).

According to some embodiments of the invention, increased yield of corn may be manifested as one or more of the following: increase in the number of plants per growing area, increase in the number of ears per plant, increase in the number of rows per ear, number of kernels per ear row, kernel weight, thousand kernel weight (1000-weight), ear length/diameter, increase oil content per kernel and increase starch content per kernel.

As mentioned, the increase of plant yield can be determined by various parameters. For example, increased yield of rice may be manifested by an increase in one or more of the following: number of plants per growing area, number of panicles per plant, number of spikelets per panicle, number of flowers per panicle, increase in the seed filling rate, increase in thousand kernel weight (1000-weight), increase oil content per seed, increase starch content per seed, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Similarly, increased yield of soybean may be manifested by an increase in one or more of the following: number of plants per growing area, number of pods per plant, number of seeds per pod, increase in the seed filling rate, increase in thousand seed weight (1000-weight), reduce pod shattering, increase oil content per seed, increase protein content per seed, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Increased yield of canola may be manifested by an increase in one or more of the following: number of plants per growing area, number of pods per plant, number of seeds per pod, increase in the seed filling rate, increase in thousand seed weight (1000-weight), reduce pod shattering, increase oil content per seed, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Increased yield of cotton may be manifested by an increase in one or more of the following: number of plants per growing area, number of bolls per plant, number of seeds per boll, increase in the seed filling rate, increase in thousand seed weight (1000-weight), increase oil content per seed, improve fiber length, fiber strength, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Oil content—The oil content of a plant can be determined by extraction of the oil from the seed or the vegetative portion of the plant. Briefly, lipids (oil) can be removed from the plant (e.g., seed) by grinding the plant tissue in the presence of specific solvents (e.g., hexane or petroleum ether) and extracting the oil in a continuous extractor. Indirect oil content analysis can be carried out using various known methods such as Nuclear Magnetic Resonance (NMR) Spectroscopy, which measures the resonance energy absorbed by hydrogen atoms in the liquid state of the sample [See for example, Conway T F. and Earle F R., 1963, Journal of the American Oil Chemists' Society; Springer Berlin/Heidelberg, ISSN: 0003-021X (Print) 1558-9331 (Online)]; the Near Infrared (NI) Spectroscopy, which utilizes the absorption of near infrared energy (1100-2500 nm) by the sample; and a method described in WO/2001/023884, which is based on extracting oil a solvent, evaporating the solvent in a gas stream which forms oil particles, and directing a light into the gas stream and oil particles which forms a detectable reflected light.

Thus, the present invention is of high agricultural value for promoting the yield of commercially desired crops (e.g., biomass of vegetative organ such as poplar wood, or reproductive organ such as number of seeds or seed biomass).

Any of the transgenic plants described hereinabove or parts thereof may be processed to produce a feed, meal, protein or oil preparation, such as for ruminant animals.

The transgenic plants described hereinabove, which exhibit an increased oil content can be used to produce plant oil (by extracting the oil from the plant).

The plant oil (including the seed oil and/or the vegetative portion oil) produced according to the method of the invention may be combined with a variety of other ingredients. The specific ingredients included in a product are determined according to the intended use. Exemplary products include animal feed, raw material for chemical modification, biodegradable plastic, blended food product, edible oil, biofuel, cooking oil, lubricant, biodiesel, snack food, cosmetics, and fermentation process raw material. Exemplary products to be incorporated to the plant oil include animal feeds, human food products such as extruded snack foods, breads, as a food binding agent, aquaculture feeds, fermentable mixtures, food supplements, sport drinks, nutritional food bars, multi-vitamin supplements, diet drinks, and cereal foods.

According to some embodiments of the invention, the oil comprises a seed oil.

According to some embodiments of the invention, the oil comprises a vegetative portion oil.

According to some embodiments of the invention, the plant cell forms a part of a plant.

As used herein the term “about” refers to ±10%.

The terms “comprises”, “comprising”, “includes”, “including”, “having” and their conjugates mean “including but not limited to”.

The term “consisting of” means “including and limited to”.

The term “consisting essentially of” means that the composition, method or structure may include additional ingredients, steps and/or parts, but only if the additional ingredients, steps and/or parts do not materially alter the basic and novel characteristics of the claimed composition, method or structure.

As used herein, the singular form “a”, “an” and “the” include plural references unless the context clearly dictates otherwise. For example, the term “a compound” or “at least one compound” may include a plurality of compounds, including mixtures thereof.

Throughout this application, various embodiments of this invention may be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible subranges as well as individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed subranges such as from 1 to 3, from 1 to 4, from 1 to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 3, 4, 5, and 6. This applies regardless of the breadth of the range.

Whenever a numerical range is indicated herein, it is meant to include any cited numeral (fractional or integral) within the indicated range. The phrases “ranging/ranges between” a first indicate number and a second indicate number and “ranging/ranges from” a first indicate number “to” a second indicate number are used herein interchangeably and are meant to include the first and second indicated numbers and all the fractional and integral numerals therebetween.

As used herein the term “method” refers to manners, means, techniques and procedures for accomplishing a given task including, but not limited to, those manners, means, techniques and procedures either known to, or readily developed from known manners, means, techniques and procedures by practitioners of the chemical, pharmacological, biological, biochemical and medical arts.

It is appreciated that certain features of the invention, which are, for clarity, described in the context of separate embodiments, may also be provided in combination in a single embodiment. Conversely, various features of the invention, which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable subcombination or as suitable in any other described embodiment of the invention. Certain features described in the context of various embodiments are not to be considered essential features of those embodiments, unless the embodiment is inoperative without those elements.

Various embodiments and aspects of the present invention as delineated hereinabove and as claimed in the claims section below find experimental support in the following examples.

EXAMPLES

Reference is now made to the following examples, which together with the above descriptions illustrate some embodiments of the invention in a non limiting fashion.

Generally, the nomenclature used herein and the laboratory procedures utilized in the present invention include molecular, biochemical, microbiological and recombinant DNA techniques. Such techniques are thoroughly explained in the literature. See, for example, “Molecular Cloning: A laboratory Manual” Sambrook et al., (1989); “Current Protocols in Molecular Biology” Volumes I-III Ausubel, R. M., ed. (1994); Ausubel et al., “Current Protocols in Molecular Biology”, John Wiley and Sons, Baltimore, Md. (1989); Perbal, “A Practical Guide to Molecular Cloning”, John Wiley & Sons, New York (1988); Watson et al., “Recombinant DNA”, Scientific American Books, New York; Birren et al. (eds) “Genome Analysis: A Laboratory Manual Series”, Vols. 1-4, Cold Spring Harbor Laboratory Press, New York (1998); methodologies as set forth in U.S. Pat. Nos. 4,666,828; 4,683,202; 4,801,531; 5,192,659 and 5,272,057; “Cell Biology: A Laboratory Handbook”, Volumes I-III Cellis, J. E., ed. (1994); “Current Protocols in Immunology” Volumes I-III Coligan J. E., ed. (1994); Stites et al. (eds), “Basic and Clinical Immunology” (8th Edition), Appleton & Lange, Norwalk, Conn. (1994); Mishell and Shiigi (eds), “Selected Methods in Cellular Immunology”, W. H. Freeman and Co., New York (1980); available immunoassays are extensively described in the patent and scientific literature, see, for example, U.S. Pat. Nos. 3,791,932; 3,839,153; 3,850,752; 3,850,578; 3,853,987; 3,867,517; 3,879,262; 3,901,654; 3,935,074; 3,984,533; 3,996,345; 4,034,074; 4,098,876; 4,879,219; 5,011,771 and 5,281,521; “Oligonucleotide Synthesis” Gait, M. J., ed. (1984); “Nucleic Acid Hybridization” Hames, B. D., and Higgins S. J., eds. (1985); “Transcription and Translation” Hames, B. D., and Higgins S. J., Eds. (1984); “Animal Cell Culture” Freshney, R. I., ed. (1986); “Immobilized Cells and Enzymes” IRL Press, (1986); “A Practical Guide to Molecular Cloning” Perbal, B., (1984) and “Methods in Enzymology” Vol. 1-317, Academic Press; “PCR Protocols: A Guide To Methods And Applications”, Academic Press, San Diego, Calif. (1990); Marshak et al., “Strategies for Protein Purification and Characterization—A Laboratory Course Manual” CSHL Press (1996); all of which are incorporated by reference as if fully set forth herein. Other general references are provided throughout this document. The procedures therein are believed to be well known in the art and are provided for the convenience of the reader. All the information contained therein is incorporated herein by reference.

General Experimental and Bioinformatics Methods

RNA extraction—Tissues growing at various growth conditions (as described below) were sampled and RNA was extracted using TRIzol Reagent from Invitrogen [Hypertext Transfer Protocol://World Wide Web (dot) invitrogen (dot) com/content (dot)cfm?pageid=469]. Approximately 30-50 mg of tissue was taken from samples. The weighed tissues were ground using pestle and mortar in liquid nitrogen and resuspended in 500 μl of TRIzol Reagent. To the homogenized lysate, 100 μl of chloroform was added followed by precipitation using isopropanol and two washes with 75% ethanol. The RNA was eluted in 30 μl of RNase-free water. RNA samples were cleaned up using Qiagen's RNeasy minikit clean-up protocol as per the manufacturer's protocol (QIAGEN Inc, CA USA). For convenience, each micro-array expression information tissue type has received an expression Set ID.

Correlation analysis—was performed for selected genes according to some embodiments of the invention, in which the characterized parameters (measured parameters according to the correlation IDs) were used as “x axis” for correlation with the tissue transcriptom which was used as the “Y axis”. For each gene and measured parameter a correlation coefficient “R” was calculated (using Pearson correlation) along with a p-value for the significance of the correlation. When the correlation coefficient (R) between the levels of a gene's expression in a certain tissue and a phenotypic performance across ecotypes/variety/hybrid is high in absolute value (between 0.5-1), there is an association between the gene (specifically the expression level of this gene) the phenotypic characteristic (e.g., improved nitrogen use efficiency, abiotic stress tolerance, yield, growth rate and the like).

Example 1 Identifying Genes which Increase Nitrogen Use Efficiency (NUE), Fertilizer Use Efficiency (FUE), Yield, Growth Rate, Vigor, Biomass, Oil Content, Abiotic Stress Tolerance (ABST) and/or Water Use Efficiency (WUE) in Plants

The present inventors have identified polynucleotides which upregulation of expression thereof in plants increases nitrogen use efficiency (NUE), fertilizer use efficiency (FUE), yield (e.g., seed yield, oil yield, biomass, grain quantity and/or quality), growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance (ABST) and/or water use efficiency (WUE) of a plant.

All nucleotide sequence datasets used here were originated from publicly available databases or from performing sequencing using the Solexa technology (e.g. Barley and Sorghum). Sequence data from 100 different plant species was introduced into a single, comprehensive database. Other information on gene expression, protein annotation, enzymes and pathways were also incorporated. Major databases used include:

-   -   Genomes     -   Arabidopsis genome [TAIR genome version 6 (Hypertext Transfer         Protocol://World Wide Web (dot) arabidopsis (dot) org/)]     -   Rice genome [IRGSP build 4.0 (Hypertext Transfer Protocol://rgp         (dot) dna (dot) affrc (dot) go (dot) jp/IRGSP/)].     -   Poplar [Populus trichocarpa release 1.1 from JGI (assembly         release v1.0) (Hypertext Transfer Protocol://World Wide Web         (dot) genome (dot) jgi-psf (dot) org/)]     -   Brachypodium [JGI 4× assembly, Hypertext Transfer         Protocol://World Wide Web (dot) brachpodium (dot) org)]     -   Soybean [DOE-JGI SCP, version Glyma0 (Hypertext Transfer         Protocol://World Wide Web (dot) phytozome (dot) net/)]     -   Grape [French-Italian Public Consortium for Grapevine Genome         Characterization grapevine genome (Hypertext Transfer         Protocol://World Wide Web (dot) genoscope (dot) cns (dot) fr/)]     -   Castobean [TIGR/J Craig Venter Institute 4x assembly [(Hypertext         Transfer Protocol://msc (dot) jcvi (dot) org/r_communis]     -   Sorghum [DOE-JGI SCP, version Sbi1 [Hypertext Transfer         Protocol://World Wide Web (dot) phytozome (dot) net/)].     -   Maize [Hypertext Transfer Protocol://maizesequence (dot) org/]     -   Cucumber [Hypertext Transfer Protocol://cucumber (dot) genomics         (dot) org (dot) cn/page/cucumber/index (dot) jsp]     -   Tomato [Hypertext Transfer Protocol://solgenomics (dot)         net/tomato/]     -   Cassava [Hypertext Transfer Protocol://World Wide Web (dot)         phytozome (dot) net/cassava (dot) php]     -   Expressed EST and mRNA sequences were extracted from the         following databases:     -   GenBank (Hypertext Transfer Protocol://World Wide Web (dot) ncbi         (dot) nlm (dot) nih (dot) gov/Genbank/).     -   RefSeq (Hypertext Transfer Protocol://World Wide Web (dot) ncbi         (dot) nlm (dot) nih (dot) gov/RefSeq/).     -   TAIR (Hypertext Transfer Protocol://World Wide Web (dot)         arabidopsis (dot) org/).     -   Protein and pathway databases     -   Uniprot [Hypertext Transfer Protocol://World Wide Web (dot)         uniprot (dot) org/].     -   AraCyc [Hypertext Transfer Protocol://World Wide Web (dot)         arabidopsis (dot) org/biocyc/index (dot) jsp].     -   ENZYME [Hypertext Transfer Protocol://expasy (dot) org/enzyme/].     -   Microarray datasets were downloaded from:     -   GEO (Hypertext Transfer Protocol://World Wide         Web.ncbi.nlm.nih.gov/geo/)     -   TAIR (Hypertext Transfer Protocol://World Wide         Web.arabidopsis.org/).     -   Proprietary micro-array data (See WO2008/122980 and Examples         3-10 below).     -   QTL and SNPs information     -   Gramene [Hypertext Transfer Protocol://World Wide Web (dot)         gramene (dot) org/qtl/].     -   Panzea [Hypertext Transfer Protocol://World Wide Web (dot)         panzea (dot) org/index (dot) html].     -   Soybean QTL: [Hypertext Transfer Protocol://World Wide Web (dot)         soybeanbreederstoolbox(dot) com/].

Database Assembly—was performed to build a wide, rich, reliable annotated and easy to analyze database comprised of publicly available genomic mRNA, ESTs DNA sequences, data from various crops as well as gene expression, protein annotation and pathway, QTLs data, and other relevant information.

Database assembly is comprised of a toolbox of gene refining, structuring, annotation and analysis tools enabling to construct a tailored database for each gene discovery project. Gene refining and structuring tools enable to reliably detect splice variants and antisense transcripts, generating understanding of various potential phenotypic outcomes of a single gene. The capabilities of the “LEADS” platform of Compugen LTD for analyzing human genome have been confirmed and accepted by the scientific community [see e.g., “Widespread Antisense Transcription”, Yelin, et al. (2003) Nature Biotechnology 21, 379-85; “Splicing of Alu Sequences”, Lev-Maor, et al. (2003) Science 300 (5623), 1288-91; “Computational analysis of alternative splicing using EST tissue information”, Xie H et al. Genomics 2002], and have been proven most efficient in plant genomics as well.

EST clustering and gene assembly—For gene clustering and assembly of organisms with available genome sequence data (Arabidopsis, rice, castorbean, grape, brachypodium, poplar, soybean, sorghum) the genomic LEADS version (GANG) was employed. This tool allows most accurate clustering of ESTs and mRNA sequences on genome, and predicts gene structure as well as alternative splicing events and anti-sense transcription.

For organisms with no available full genome sequence data, “expressed LEADS” clustering software was applied.

Gene annotation—Predicted genes and proteins were annotated as follows:

Sequences blast search [Hypertext Transfer Protocol://blast (dot) ncbi (dot) nlm (dot) nih (dot) gov/Blast (dot) cgi] against all plant UniProt [Hypertext Transfer Protocol://World Wide Web (dot) uniprot (dot) org/] was performed. Open reading frames of each putative transcript were analyzed and longest ORF with higher number of homologues was selected as predicted protein of the transcript. The predicted proteins were analyzed by InterPro [Hypertext Transfer Protocol://World Wide Web (dot) ebi (dot) ac (dot) uk/interpro/].

Blast against proteins from AraCyc and ENZYME databases was used to map the predicted transcripts to AraCyc pathways.

Predicted proteins from different species were compared using blast algorithm [Hypertext Transfer Protocol://World Wide Web (dot) ncbi (dot) nlm (dot) nih (dot) gov/Blast (dot) cgi] to validate the accuracy of the predicted protein sequence, and for efficient detection of orthologs.

Gene expression profiling—Several data sources were exploited for gene expression profiling, namely microarray data and digital expression profile (see below). According to gene expression profile, a correlation analysis was performed to identify genes which are co-regulated under different development stages and environmental conditions and associated with different phenotypes.

Publicly available microarray datasets were downloaded from TAIR and NCBI GEO sites, renormalized, and integrated into the database. Expression profiling is one of the most important resource data for identifying genes important for yield.

A digital expression profile summary was compiled for each cluster according to all keywords included in the sequence records comprising the cluster. Digital expression, also known as electronic Northern Blot, is a tool that displays virtual expression profile based on the EST sequences forming the gene cluster. The tool provides the expression profile of a cluster in terms of plant anatomy (e.g., the tissue/organ in which the gene is expressed), developmental stage (the developmental stages at which a gene can be found) and profile of treatment (provides the physiological conditions under which a gene is expressed such as drought, cold, pathogen infection, etc). Given a random distribution of ESTs in the different clusters, the digital expression provides a probability value that describes the probability of a cluster having a total of N ESTs to contain X ESTs from a certain collection of libraries. For the probability calculations, the following is taken into consideration: a) the number of ESTs in the cluster, b) the number of ESTs of the implicated and related libraries, c) the overall number of ESTs available representing the species. Thereby clusters with low probability values are highly enriched with ESTs from the group of libraries of interest indicating a specialized expression.

Recently, the accuracy of this system was demonstrated by Portnoy et al., 2009 (Analysis Of The Melon Fruit Transcriptome Based On 454 Pyrosequencing) in: Plant & Animal Genomes XVII Conference, San Diego, Calif. Transcriptomic analysis, based on relative EST abundance in data was performed by 454 pyrosequencing of cDNA representing mRNA of the melon fruit. Fourteen double strand cDNA samples obtained from two genotypes, two fruit tissues (flesh and rind) and four developmental stages were sequenced. GS FLX pyrosequencing (Roche/454 Life Sciences) of non-normalized and purified cDNA samples yielded 1,150,657 expressed sequence tags (ESTs) that assembled into 67,477 unigenes (32,357 singletons and 35,120 contigs). Analysis of the data obtained against the Cucurbit Genomics Database [Hypertext Transfer Protocol://World Wide Web (dot) icugi (dot) org/] confirmed the accuracy of the sequencing and assembly. Expression patterns of selected genes fitted well their qRT-PCR data.

Overall, 257 genes were identified to have a major impact on nitrogen use efficiency, fertilizer use efficiency, yield (e.g., seed yield, oil yield, grain quantity and/or quality), growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency when expression thereof is increased in plants. The identified genes, their curated polynucleotide and polypeptide sequences, as well as their updated sequences according to GenBank database are summarized in Table 1, hereinbelow.

TABLE 1 Identified polynucleotides for increasing nitrogen use efficiency, fertilizer use efficiency, yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant Polyn. Polyp. Gene Name Cluster Name Organism SEQ ID NO: SEQ ID NO: LNU1 arabidopsis|gb165|AT5G11630 arabidopsis 1 468 LNU2 rice|gb157.2|BI798989 rice 2 469 LNU3 rice|gb157.2|AK106493 rice 3 470 LNU4 barley|gb157.3|BI953357 barley 4 471 LNU5 barley|gb157.3|BE421774 barley 5 472 LNU6 soybean|gb166|BI942460 soybean 6 473 LNU7 soybean|gb166|CD398173 soybean 7 474 LNU8 arabidopsis|gb165|AT3G18200 arabidopsis 8 475 LNU9 rice|gb157.2|AU066136 rice 9 476 LNU10 rice|gb157.2|CB678538 rice 10 477 LNU11 rice|gb157.2|CB641645 rice 11 478 LNU12 rice|gb157.2|Y11415 rice 12 479 LNU13 rice|gb157.2|BI805840 rice 13 480 LNU14 arabidopsis|gb165|AT2G37860 arabidopsis 14 481 LNU15 arabidopsis|gb165|AT3G07420 arabidopsis 15 482 LNU17 rice|gb157.2|BF430745 rice 16 483 LNU19 rice|gb157.2|CB642397 rice 17 484 LNU20 tomato|gb164|BG131270 tomato 18 485 LNU23 arabidopsis|gb165|AT1G23120 arabidopsis 19 486 LNU24 arabidopsis|gb165|AT1G33110 arabidopsis 20 487 LNU25 sorghum|gb161.xeno|BE355836 sorghum 21 488 LNU27 barley|gb157.3|BE196470 barley 22 489 LNU28 barley|gb157.3|AL500488 barley 23 490 LNU29 tomato|gb164|AI487919 tomato 24 491 LNU32 sorghum|gb16.xeno|AW671708 sorghum 25 492 LNU33 soybean|gb166|CD408405 soybean 26 493 LNU34 rice|gb157.2|AU030308 rice 27 494 LNU35 wheat|gb164|BE442655 wheat 28 495 LNU36 soybean|gb168|BE347766 soybean 29 496 LNU37 rice|gb157.2|CA767513 rice 30 497 LNU40 rice|gb157.2|OSU76004 rice 31 498 LNU43 soybean|gb166|AW349541 soybean 32 499 LNU44 soybean|gb166|GMU12150 soybean 33 500 LNU45 soybean|gb166|AW508359 soybean 34 501 LNU46 soybean|gb166|AW348273 soybean 35 502 LNU48 rice|gb157.3|BI806333 rice 36 503 LNU50 rice|gb157.3|AK070604 rice 37 504 LNU51 rice|gb157.3|AA751405 rice 38 505 LNU52 rice|gb157.3|AF042333 rice 39 506 LNU53 soybean|gb168|CA782562 soybean 40 507 LNU54 soybean|gb168|BF518437 soybean 41 508 LNU55 soybean|gb168|BQ080255 soybean 42 509 LNU56 soybean|gb168|BE352719 soybean 43 510 LNU57 wheat|gb164|BE405851 wheat 44 511 LNU58 wheat|gb164|BE585823 wheat 45 512 LNU59 wheat|gb164|BE515786 wheat 46 513 LNU60 wheat|gb164|BQ901296 wheat 47 514 LNU61 wheat|gb164|BE498157 wheat 48 515 LNU63 wheat|gb164|BF429186 wheat 49 516 LNU64 wheat|gb164|BU100011 wheat 50 517 LNU65 rice|gb157.3|C28856 rice 51 518 LNU67 rice|gb157.3|AA749717 rice 52 519 LNU68 rice|gb157.3|BM421254 rice 53 520 LNU69 rice|gb157.3|AF458088 rice 54 521 LNU70 rice|gb170|OS11G48080 rice 55 522 LNU71 rice|gb157.3|AF210325 rice 56 523 LNU72 barley|gb157.3|BI954541 barley 57 524 LNU73 rice|gb157.3|AA754527 rice 58 525 LNU74 poplar|gb170|AI164893 poplar 59 526 LNU75 soybean|gb168|AW690409 soybean 60 527 LNU76 rice|gb157.3|AA752216 rice 61 528 LNU79 cotton|gb164|BF272356 cotton 62 529 LNU81 barley|gb157.3|BE421380 barley 63 530 LNU82 rice|gb157.3|AU031357 rice 64 531 LNU83 soybean|gb168|AW471606 soybean 65 532 LNU84 sorghum|gb161.xeno|AI714503 sorghum 66 533 LNU85 sorghum|gb161.xeno|AI941787 sorghum 67 534 LNU86 maize|gb169.2|AI941972 maize 68 535 LNU87 sorghum|gb161.crp|BM325119 sorghum 69 536 LNU89 wheat|gb164|BQ236209 wheat 70 537 LNU94 tomato|gb164|BF113903 tomato 71 538 LNU95 soybean|gb168|BQ741102 soybean 72 539 LNU96 rice|gbl57.3|AA751884 rice 73 540 LNU98 maize|gb164|AI947517 maize 74 541 LNU100 cotton|gb1641|AI055197 cotton 75 542 LNU101 rice|gb157.3|NM001061106 rice 76 543 LNU104 soybean|gb168|BQ610458 soybean 77 544 LNU105 wheat|gb164|BG606394 wheat 78 545 LNU106 wheat|gb164|BF201718 wheat 79 546 LNU107 rice|gb157.3|BE040237 rice 80 547 LNU109 rice|gb157.3|AU032452 rice 81 548 LNU110 rice|gb157.3|CA755769 rice 82 549 LNU112 rice|gb157.3|AU057246 rice 83 550 LNU113 maize|gb164|AA054793 maize 84 551 LNU114 rice|gb157.3|AA752410 rice 85 552 LNU115 rice|gb157.3|CB635059 rice 86 553 LNU116 rice|gb170|OS10G28240 rice 87 554 LNU117 rice|gb157.3|AU081366 rice 88 555 LNU118 rice|gb157.3|AU098344 rice 89 556 LNU119 rice|gb157.3|AK063703 rice 90 557 LNU120 rice|gb170|OS02G37380 rice 91 558 LNU121 rice|gb157.3|AU166339 rice 92 559 LNU122 rice|gb157.3|BI813219 rice 93 560 LNU123 arabidopsis|gb165|AT1G63850 arabidopsis 94 561 LNU124 arabidopsis|gb165|AT5G54130T2 arabidopsis 95 562 LNU126 arabidopsis|gb165|AT5G58770 arabidopsis 96 563 LNU127 arabidopsis|gb165|AT5G61820 arabidopsis 97 564 LNU128 arabidopsis|gb165|AT1G21690 arabidopsis 98 565 LNU129 arabidopsis|gb165|AT1G53450 arabidopsis 99 566 LNU130 arabidopsis|gb165|AT1G76560 arabidopsis 100 567 LNU131 arabidopsis|gb165|AT2G41950 arabidopsis 101 568 LNU132 arabidopsis|gb165|AT1G68440 arabidopsis 102 569 LNU133 arabidopsis|gb165|AT1G72020 arabidopsis 103 570 LNU134 arabidopsis|gb165|AT4G12000 arabidopsis 104 571 LNU135 arabidopsis|gb165|AT4G38800 arabidopsis 105 572 LNU136 arabidopsis|gb165|AT3G26440 arabidopsis 106 573 LNU138 barley|gb157.3|AL500952 barley 107 574 LNU140 arabidopsis|gb165|AT1G62430 arabidopsis 108 575 LNU141 wheat|gb164|BE604062 wheat 109 576 LNU142 barley|gb157.3|AJ472814 barley 110 577 LNU143 cotton|gb164|BG443936 cotton 111 578 LNU146 rice|gb157.3|AA754467 rice 112 579 LNU147 cotton|gb164|DT462051 cotton 113 580 LNU148 soybean|gb168|CD394513 soybean 114 581 LNU149 rice|gb157.3|AK110423 rice 115 582 LNU150 cotton|gb164|AW186819 cotton 116 583 LNU153 rice|gb157.3|AU166793 rice 117 584 LNU154 cotton|gb164|AI054586 cotton 118 585 LNU155 cotton|gb164|C0101542 cotton 119 586 LNU157 soybean|gb166|CF921687 soybean 120 587 LNU158 cotton|gb164|CO082594 cotton 121 588 LNU161 soybean|gb168|BE661583 soybean 122 589 LNU168 sorghum|gb161.crp|AW927746 sorghum 123 590 LNU170 arabidopsis|gb165|AT5G40060 arabidopsis 124 591 LNU171 barley|gb157.3|AL501130 barley 125 592 LNU172 barley|gb157.3|BI777246 barley 126 593 LNU173 barley|gb157.3|BE437951 barley 127 594 LNU175 arabidopsis|gb165|AT4G28290 arabidopsis 128 595 LNU176 rice|gb157.3|AU062564 rice 129 596 LNU177 arabidopsis|gb165|AT1G67740 arabidopsis 130 597 LNU178 arabidopsis|gb165|AT1G18300 arabidopsis 131 598 LNU179 arabidopsis|gb165|AT1G53560 arabidopsis 132 599 LNU180 arabidopsis|gb165|AT1G70230 arabidopsis 133 600 LNU181 arabidopsis|gb165|AT3G57940 arabidopsis 134 601 LNU182 arabidopsis|gb165|AT3G08980 arabidopsis 135 602 LNU183 arabidopsis|gb165|AT1G58340 arabidopsis 136 603 LNU184 arabidopsis|gb165|AT3G52230 arabidopsis 137 604 LNU185 arabidopsis|gb165|AT3G63160 arabidopsis 138 605 LNU186 arabidopsis|gb165|AT2G03350 arabidopsis 139 606 LNU187 arabidopsis|gb165|AT5G01540 arabidopsis 140 607 LNU188 soybean|gb166|BU547183 soybean 141 608 LNU189 rice|gb157.3|BE230329 rice 142 609 LNU190 canola|gb161|DY007527 canola 143 610 LNU191 rice|gb157.3|CA753062 rice 144 611 LNU192 rice|gb157.3|BE040846 rice 145 612 LNU196 rice|gb157.3|BI809290 rice 146 613 LNU198 cotton|gb164|CO078561 cotton 147 614 LNU200 tomato|gb164|BG791292 tomato 148 615 LNU202 sorghum|gb161.xeno|BE362397 sorghum 149 616 LNU206 arabidopsis|gb165|AT2G31890 arabidopsis 150 617 LNU207 arabidopsis|gb165|AT1G70260 arabidopsis 151 618 LNU210 arabidopsis|gb165|AT3G61060 arabidopsis 152 619 LNU211 arabidopsis|gb165|AT5G06270 arabidopsis 153 620 LNU212 arabidopsis|gb165|AT1G28400 arabidopsis 154 621 LNU213 arabidopsis|gb165|AT5G11690 arabidopsis 155 622 LNU214 arabidopsis|gb165|AT1G19020 arabidopsis 156 623 LNU215 arabidopsis|gb165|AT1G08570 arabidopsis 157 624 LNU216 rice|gb157.3|BI804955 rice 158 625 LNU217 rice|gb157.3|AT003632 rice 159 626 LNU218 arabidopsis|gb165|AT5G35460 arabidopsis 160 627 LNU219 arabidopsis|gb165|AT4G19400 arabidopsis 161 628 LNU220 rice|gb157.3|AW155256 rice 162 629 LNU222 wheat|gb164|BE400657 wheat 163 630 LNU223 rice|gb157.3|BI798260 rice 164 631 LNU224 barley|gb157.3|BF628111 barley 165 632 LNU225 arabidopsis|gb165|AT4G27050 arabidopsis 166 633 LNU228 barley|gb157.3|BF622377 barley 167 634 LNU229 tomato|gb164|AI484048 tomato 168 635 LNU230 rice|gb157.3|AU091786 rice 169 636 LNU232 rice|gb157.2|CA754695 rice 170 637 LNU234 arabidopsis|gb165|AT1G22140 arabidopsis 171 638 LNU235 arabidopsis|gb165|AT1G33590 arabidopsis 172 639 LNU236 cotton|gb164|AI728962 cotton 173 640 LNU239 rice|gb157.2|BE530901 rice 174 641 LNU240 barley|gb157.3|AV914239 barley 175 642 LNU241 rice|gb157.2|CA756471 rice 176 643 LNU242 arabidopsis|gb165|AT4G01650 arabidopsis 177 644 LNU243 barley|gb157.3|BQ467891 barley 178 645 LNU244 barley|gb157.3|AV932151 barley 179 646 LNU245 tomato|gb164|AI486625 tomato 180 647 LNU246 tomato|gb164|AI896232 tomato 181 648 LNU247 arabidopsis|gb165|AT5G15170 arabidopsis 182 649 LNU249 arabidopsis|gb165|AT5G04980 arabidopsis 183 650 LNU250 arabidopsis|gb165|AT1G30860 arabidopsis 184 651 LNU251 arabidopsis|gb165|AT4G04940 arabidopsis 185 652 LNU253 soybean|gb166|CD407540 soybean 186 653 LNU254 arabidopsis|gb165|AT1G47670 arabidopsis 187 654 LNU255 arabidopsis|gb165|AT2G42760 arabidopsis 188 655 LNU256 arabidopsis|gb165|AT2G43920 arabidopsis 189 656 LNU257 arabidopsis|gb165|AT3G12090 arabidopsis 190 657 LNU258 arabidopsis|gb165|AT4G37330 arabidopsis 191 658 LNU260 arabidopsis|gb165|AT5G07020 arabidopsis 192 659 LNU261 arabidopsis|gb165|AT5G48470 arabidopsis 193 660 LNU262 arabidopsis|gb165|AT5G49900 arabidopsis 194 661 LNU263 barley|gb157.3|AL502706 barley 195 662 LNU265 maize|gb164|AI396555 maize 196 663 LNU265 maize|gb164|AI396555 maize 196 705 LNU266 maize|gb164|AI438792 maize 197 664 LNU267 maize|gb164|AI973407 maize 198 665 LNU268 maize|gb164|BE123241 maize 199 666 LNU271 rice|gb157.2|AU089771 rice 200 667 LNU274 rice|gb157.3|BI305442 rice 201 668 LNU275 rice|gb170|OS09G35600 rice 202 669 LNU276 rice|gb157.3|AA753720 rice 203 670 LNU277 rice|gb157.3|CV723478 rice 204 671 LNU278 sorghum|gb161.xeno|AW671348 sorghum 205 672 LNU279 sorghum|gb161.xeno|AW677534 sorghum 206 673 LNU280 sorghum|gb161.crp|BM660677 sorghum 207 674 LNU282 soybean|gb166|BI968975 soybean 208 675 LNU284 soybean|gb166|CA851742 soybean 209 676 LNU287 soybean|gb168|CD394819 soybean 210 677 LNU288 tomato|gb164|BG134658 tomato 211 678 LNU289 tomato|gb164|BG123295 tomato 212 679 LNU222_H6 sorghum|gb161.crp|AW678240 sorghum 213 680 LNU125 arabidopsis|gb165|AT4G04925 arabidopsis 214 — LNU201 rice|gb157.3|BI801545 rice 215 — LNU233 rice|gb157.3|AK107825 rice 216 — LNU3 rice|gb170|OS03G51530 rice 217 470 LNU29 tomato|gb164|AI487919 tomato 218 681 LNU33 soybean|gb168|AL374064 soybean 219 493 LNU35 wheat|gb164|BE442655 wheat 220 682 LNU36 soybean|gb168|BE347766 soybean 221 496 LNU53 soybean|gb168|CA782562 soybean 222 683 LNU55 soybean|gb168|BQ080255 soybean 223 684 LNU57 wheat|gb164|BE405851 wheat 224 685 LNU60 wheat|gb164|BQ901296 wheat 225 686 LNU74 poplar|gb157.2|AI164893 poplar 226 526 LNU83 soybean|gb168|AW471606 soybean 227 687 LNU89 wheat|gb164|BQ236209 wheat 228 688 LNU101 rice|gb157.3|NM001061106 rice 229 689 LNU105 wheat|gb164|BG606394 wheat 230 690 LNU113 maize|gb169.2|AA054793 maize 231 691 LNU114 rice|gb157.3|AA752410 rice 232 692 LNU115 rice|gb157.3|CB635059 rice 233 693 LNU123 arabidopsis|gb165|AT1G63850 arabidopsis 234 561 LNU126 arabidopsis|gb165|AT5G58770 arabidopsis 235 563 LNU143 cotton|gb164|BG443936 cotton 236 694 LNU147 cotton|gb164|DT462051 cotton 237 580 LNU148 soybean|gb168|CD394513 soybean 238 695 LNU158 cotton|gb164|CO082594 cotton 239 696 LNU170 arabidopsis|gb165|AT5G40060 arabidopsis 240 697 LNU190 canola|gb161|DY007527 canola 241 610 LNU192 rice|gb157.3|BE040846 rice 242 698 LNU198 cotton|gb164|C0078561 cotton 243 614 LNU200 tomato|gb164|BG791292 tomato 244 699 LNU202 sorghum|gb161.xeno|BE362397 sorghum 245 700 LNU229 tomato|gb164|AI484048 tomato 246 701 LNU236 cotton|gb164|AI728962 cotton 247 640 LNU240 barley|gb157.3|AV914239 barley 248 702 LNU241 rice|gb170|OS12G40330 rice 249 643 LNU242 arabidopsis|gb165|AT4G01650 arabidopsis 250 703 LNU243 barley|gb157.3|BQ467891 barley 251 645 LNU244 barley|gb157.3|AV932151 barley 252 704 LNU249 arabidopsis|gb165|AT5G04980 arabidopsis 253 650 LNU257 arabidopsis|gb165|AT3G12090 arabidopsis 254 657 LNU266 maize|gb164|AI438792 maize 255 706 LNU289 tomato|gb164|BG123295 tomato 256 679 LNU222_H6 sorghum|gb161.crp|AW678240 sorghum 257 680 Table 1. “Polyp.” = polypeptide; “Polyn.” - Polynucleotide.

Example 2 Identification of Homologous Sequences that Increase Nitrogen Use Efficiency, Fertilizer Use Efficiency, Yield, Growth Rate, Vigor, Biomass, Oil Content, Abiotic Stress Tolerance and/or Water Use Efficiency in Plants

The concepts of orthology and paralogy have recently been applied to functional characterizations and classifications on the scale of whole-genome comparisons. Orthologs and paralogs constitute two major types of homologs: The first evolved from a common ancestor by specialization, and the latter is related by duplication events. It is assumed that paralogs arising from ancient duplication events are likely to have diverged in function while true orthologs are more likely to retain identical function over evolutionary time.

To further investigate and identify putative orthologs of the genes affecting nitrogen use efficiency, fertilizer use efficiency, yield (e.g., seed yield, oil yield, biomass, grain quantity and/or quality), growth rate, vigor, biomass, oil content, abiotic stress tolerance and/or water use efficiency, all sequences were aligned using the BLAST (/Basic Local Alignment Search Tool/). Sequences sufficiently similar were tentatively grouped. These putative orthologs were further organized under a Phylogram—a branching diagram (tree) assumed to be a representation of the evolutionary relationships among the biological taxa. Putative ortholog groups were analyzed as to their agreement with the phylogram and in cases of disagreements these ortholog groups were broken accordingly. Expression data was analyzed and the EST libraries were classified using a fixed vocabulary of custom terms such as developmental stages (e.g., genes showing similar expression profile through development with up regulation at specific stage, such as at the seed filling stage) and/or plant organ (e.g., genes showing similar expression profile across their organs with up regulation at specific organs such as seed). The annotations from all the ESTs clustered to a gene were analyzed statistically by comparing their frequency in the cluster versus their abundance in the database, allowing the construction of a numeric and graphic expression profile of that gene, which is termed “digital expression”. The rationale of using these two complementary methods with methods of phenotypic association studies of QTLs, SNPs and phenotype expression correlation is based on the assumption that true orthologs are likely to retain identical function over evolutionary time. These methods provide different sets of indications on function similarities between two homologous genes, similarities in the sequence level—identical amino acids in the protein domains and similarity in expression profiles.

The search and identification of homologous genes involves the screening of sequence information available, for example, in public databases, which include but are not limited to the DNA Database of Japan (DDBJ), Genbank, and the European Molecular Biology Laboratory Nucleic Acid Sequence Database (EMBL) or versions thereof or the MIPS database. A number of different search algorithms have been developed, including but not limited to the suite of programs referred to as BLAST programs. There are five implementations of BLAST, three designed for nucleotide sequence queries (BLASTN, BLASTX, and TBLASTX) and two designed for protein sequence queries (BLASTP and TBLASTN) (Coulson, Trends in Biotechnology: 76-80, 1994; Birren et al., Genome Analysis, I: 543, 1997). Such methods involve alignment and comparison of sequences. The BLAST algorithm calculates percent sequence identity and performs a statistical analysis of the similarity between the two sequences. The software for performing BLAST analysis is publicly available through the National Centre for Biotechnology Information. Other such software or algorithms are GAP, BESTFIT, FASTA and TFASTA. GAP uses the algorithm of Needleman and Wunsch (J. Mol. Biol. 48: 443-453, 1970) to find the alignment of two complete sequences that maximizes the number of matches and minimizes the number of gaps.

The homologous genes may belong to the same gene family. The analysis of a gene family may be carried out using sequence similarity analysis. To perform this analysis one may use standard programs for multiple alignments e.g. Clustal W. A neighbor-joining tree of the proteins homologous to the genes of some embodiments of the invention may be used to provide an overview of structural and ancestral relationships. Sequence identity may be calculated using an alignment program as described above. It is expected that other plants will carry a similar functional gene (orthologue) or a family of similar genes and those genes will provide the same preferred phenotype as the genes presented here. Advantageously, these family members may be useful in the methods of some embodiments of the invention. Example of other plants include, but not limited to, barley (Hordeum vulgare), Arabidopsis (Arabidopsis thaliana), maize (Zea mays), cotton (Gossypium), Oilseed rape (Brassica napus), Rice (Oryza sativa), Sugar cane (Saccharum officinarum), Sorghum (Sorghum bicolor), Soybean (Glycine max), Sunflower (Helianthus annuus), Tomato (Lycopersicon esculentum) and Wheat (Triticum aestivum)

The above-mentioned analyses for sequence homology is preferably carried out on a full-length sequence, but may also be based on a comparison of certain regions such as conserved domains. The identification of such domains, would also be well within the realm of the person skilled in the art and would involve, for example, a computer readable format of the nucleic acids of some embodiments of the invention, the use of alignment software programs and the use of publicly available information on protein domains, conserved motifs and boxes. This information is available in the PRODOM (Hypertext Transfer Protocol://World Wide Web (dot) biochem (dot) ucl (dot) ac (dot) uk/bsm/dbbrowser/protocol/prodomqry (dot) html), PIR (Hypertext Transfer Protocol://pir (dot) Georgetown (dot) edu/) or Pfam (Hypertext Transfer Protocol://World Wide Web (dot) sanger (dot) ac (dot) uk/Software/Pfam/) database. Sequence analysis programs designed for motif searching may be used for identification of fragments, regions and conserved domains as mentioned above. Preferred computer programs include, but are not limited to, MEME, SIGNALSCAN, and GENESCAN.

A person skilled in the art may use the homologous sequences provided herein to find similar sequences in other species and other organisms. Homologues of a protein encompass, peptides, oligopeptides, polypeptides, proteins and enzymes having amino acid substitutions, deletions and/or insertions relative to the unmodified protein in question and having similar biological and functional activity as the unmodified protein from which they are derived. To produce such homologues, amino acids of the protein may be replaced by other amino acids having similar properties (conservative changes, such as similar hydrophobicity, hydrophilicity, antigenicity, propensity to form or break a-helical structures or 3-sheet structures). Conservative substitution Tables are well known in the art [see for example Creighton (1984) Proteins. W.H. Freeman and Company]. Homologues of a nucleic acid encompass nucleic acids having nucleotide substitutions, deletions and/or insertions relative to the unmodified nucleic acid in question and having similar biological and functional activity as the unmodified nucleic acid from which they are derived.

Polynucleotides and polypeptides with significant homology to the identified genes described in Table 1 (Example 1 above) were identified from the databases using BLAST software using the Blastp and tBlastn algorithms. The query polypeptide sequences were SEQ ID NOs: 468-706 (which are encoded by the polynucleotides SEQ ID NOs:1-257, shown in Table 1 above) and SEQ ID NOs:707-784 (which are encoded by the cloned genes SEQ ID NOs:258-467, shown in Table 59 and the identified homologous sequences are provided in Table 2, below.

TABLE 2 Homologues of the identified genes/polypeptides for increasing nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant Hom. Polyp. to Polyn. Hom. to SEQ SEQ % SEQ ID Gene ID ID global NO: Name Cluster Name NO: NO: identity Algor. 785 LNU1 canola|10v1|CD822833 3042 468 82.8 globlastp 786 LNU1 canola|gb161|CD822833 3042 468 82.8 globlastp 787 LNU1 radish|gb164|EW724281 3043 468 82.8 globlastp 788 LNU1 canola|10v1|CD819354 3044 468 81.9 globlastp 789 LNU1 b_oleracea|gb161|EE534144 3045 468 81.7 globlastp 790 LNU1 radish|gb164|FD530209 3046 468 81.7 globlastp 791 LNU1 b_rapa|gb162|EX016038 3047 468 81.1 globlastp 792 LNU1 b_oleracea|gb161|DY026134 3048 468 80.9 globlastp 793 LNU1 canola|gb161|CD819354 3049 468 80.9 globlastp 794 LNU2 leymus|gb166|EG388463 3050 469 85 globlastp 795 LNU2 wheat|gb164|BE427374 3051 469 85 globlastp 796 LNU2 barley|gb157SOLEXA|AL507333 3052 469 84.5 globlastp 797 LNU2 maize|gb170|AI691484 3053 469 83.6 globlastp 798 LNU2 sugarcane|10v1|AA525691 3054 469 83.3 globlastp 799 LNU2 sugarcane|gb157.3|AA525691 3055 469 82.9 globlastp 800 LNU2 sorghum|09v1|SB10G006850 3056 469 82.5 globlastp 801 LNU2 sorghum|gb161.crp|AI881329 3056 469 82.5 globlastp 802 LNU2 switchgrass|gb167|FE630265 3057 469 81.9 globlastp 803 LNU2 maize|gb170|AI967022 3058 469 81.1 globlastp 804 LNU2 brachypodium|09v1|DV476481 3059 469 81 globlastp 805 LNU2 brachypodium|gb169|BE427374 3059 469 81 globlastp 806 LNU5 wheat|gb164|BE428356 3060 472 98.1 globlastp 807 LNU5 wheat|gb164|BQ806386 3061 472 97.7 globlastp 808 LNU5 leymus|gb166|EG389542 3062 472 97.2 globlastp 809 LNU5 oat|10v1|GR347048 3063 472 90.3 globlastp 810 LNU6 soybean|gb168|BE660452 3064 473 90.3 globlastp 811 LNU6 bean|gb167|CA901464 3065 473 85.8 globlastp 812 LNU6 cowpea|gb166|FF389080 3066 473 83.2 globlastp 813 LNU6 liquorice|gb171|FS239924 3067 473 80.9 globlastp 814 LNU6 peanut|gb167|AY639025 3068 473 80.6 globlastp 815 LNU6 peanut|gb171|AY639025 3069 473 80.6 globlastp 816 LNU6 lotus|09v1|LLBF177846 3070 473 80.3 globlastp 817 LNU7 chickpea|09v2|GR392103 3071 474 98.4 globlastp 817 LNU27 chickpea|09v2|GR392103 3071 489 80 glotblastn 818 LNU7 liquorice|gb171|FS238627 3072 474 98.4 globlastp 818 LNU27 liquorice|gb171|FS238627 3072 489 80 glotblastn 819 LNU7 liquorice|gb171|FS260230 3072 474 98.4 globlastp 819 LNU27 liquorice|gb171|FS260230 3072 489 80 glotblastn 820 LNU7 cacao|gb167|CU470501 3073 474 98.4 globlastp 820 LNU27 cacao|gb167|CU470501 3073 489 80 glotblastn 821 LNU7 cassava|09v1|DV445520 3072 474 98.4 globlastp 821 LNU27 cassava|09v1|DV445520 3072 489 80 glotblastn 822 LNU7 cassava|gb164|DV445520 3072 474 98.4 globlastp 822 LNU27 cassava|gb164|DV445520 3072 489 80 glotblastn 823 LNU7 cotton|gb164|BE054360 3073 474 98.4 globlastp 823 LNU27 cotton|gb164|BE054360 3073 489 80 glotblastn 824 LNU7 cotton|gb164|ES793421 3073 474 98.4 globlastp 824 LNU27 cotton|gb164|ES793421 3073 489 80 glotblastn 825 LNU7 medicago|09v1|AL377934 3071 474 98.4 globlastp 825 LNU27 medicago|09v1|AL377934 3071 489 80 glotblastn 826 LNU7 medicago|gb157.2|AL377934 3071 474 98.4 globlastp 826 LNU27 medicago|gb157.2|AL377934 3071 489 80 glotblastn 827 LNU7 soybean|gb168|AI967471 3072 474 98.4 globlastp 827 LNU27 soybean|gb168|AI967471 3072 489 80 glotblastn 828 LNU7 soybean|gb168|AW348687 3072 474 98.4 globlastp 828 LNU27 soybean|gb168|AW348687 3072 489 80 glotblastn 829 LNU7 chickpea|09v2|FE668992 3074 474 96.72 glotblastn 829 LNU27 chickpea|09v2|FE668992 3074 489 80 glotblastn 830 LNU7 pigeonpea|gb171|GR471306 3075 474 96.7 globlastp 830 LNU27 pigeonpea|gb171|GR471306 3075 489 80 glotblastn 831 LNU7 bean|gb167|CA897804 3076 474 96.7 globlastp 831 LNU27 bean|gb167|CA897804 3076 489 80 glotblastn 832 LNU7 bean|gb167|FD780529 3076 474 96.7 globlastp 832 LNU27 bean|gb167|FD780529 3076 489 80 glotblastn 833 LNU7 castorbean|09v1|XM002519154 3077 474 96.7 globlastp 833 LNU27 castorbean|09v1|XM002519154 3077 489 80.3 globlastp 834 LNU7 castorbean|gb160|MDL29889M003271 3077 474 96.7 globlastp 834 LNU27 castorbean|gb160|MDL29889M003271 3077 489 80.3 globlastp 835 LNU7 cowpea|gb166|FC459169 3076 474 96.7 globlastp 835 LNU27 cowpea|gb166|FC459169 3076 489 80 glotblastn 836 LNU7 cowpea|gb166|FF384333 3076 474 96.7 globlastp 836 LNU27 cowpea|gb166|FF384333 3076 489 80 glotblastn 837 LNU7 soybean|gb168|CD391265 3076 474 96.7 globlastp 837 LNU27 soybean|gb168|CD391265 3076 489 80 glotblastn 838 LNU7 heritiera|10v1|SRR005794S0008204 3078 474 95.1 globlastp 838 LNU27 heritiera|10v1|SRR005794S0008204 3078 489 80 glotblastn 839 LNU7 cacao|gb167|CU492958 3079 474 95.1 globlastp 840 LNU7 cotton|gb164|BF274438 3080 474 95.1 globlastp 840 LNU27 cotton|gb164|BF274438 3080 489 80 glotblastn 841 LNU7 kiwi|gb166|FG419099 3081 474 95.1 globlastp 842 LNU7 papaya|gb165|EX229339 3082 474 95.1 globlastp 842 LNU27 papaya|gb165|EX229339 3082 489 80 glotblastn 843 LNU7 medicago|09v1|LLCO511931 3083 474 93.4 globlastp 844 LNU7 bruguiera|gb166|BP940274 3084 474 93.4 globlastp 844 LNU27 bruguiera|gb166|BP940274 3084 489 80.3 globlastp 845 LNU7 cassava|09v1|CK646795 3085 474 93.4 globlastp 846 LNU7 grape|gb160|BQ792422 3086 474 93.4 globlastp 847 LNU7 kiwi|gb166|FG400845 3087 474 93.4 globlastp 848 LNU7 kiwi|gb166|FG434680 3088 474 93.4 globlastp 849 LNU7 lotus|09v1|AI967471 3089 474 93.4 globlastp 850 LNU7 lotus|gb157.2|AI967471 3089 474 93.4 globlastp 851 LNU7 medicago|09v1|AW171649 3090 474 93.4 globlastp 852 LNU7 medicago|gb157.2|AW171649 3090 474 93.4 globlastp 853 LNU7 poplar|gb170|AI164188 3091 474 93.4 globlastp 854 LNU7 poplar|10v1|BI127039 3092 474 93.4 globlastp 855 LNU7 poplar|gb170|BI127039 3092 474 93.4 globlastp 856 LNU7 jatropha|09v1|FM887189 3093 474 91.8 globlastp 857 LNU7 rhizophora|10v1|SRR005793S0035789 3094 474 91.8 globlastp 857 LNU27 rhizophora|10v1|SRR005793S0035789 3094 489 80.3 globlastp 858 LNU7 tea|10v1|CV014009 3095 474 91.8 globlastp 859 LNU7 bean|gb167|FD789886 3096 474 91.8 glotblastn 860 LNU7 chestnut|gb170|SRR006295S0000269 3097 474 91.8 globlastp 861 LNU7 cotton|gb164|BF270755 3098 474 91.8 globlastp 861 LNU27 cotton|gb164|BF270755 3098 489 80 glotblastn 862 LNU7 peanut|gb167|CX128150 3099 474 91.8 globlastp 863 LNU7 peanut|gb171|CX128150 3099 474 91.8 globlastp 864 LNU7 peanut|gb171|EE126662 3099 474 91.8 globlastp 865 LNU7 poplar|10v1|AI164188 3100 474 91.8 globlastp 866 LNU7 spurge|gb161|BG354130 3101 474 91.8 globlastp 866 LNU27 spurge|gb161|BG354130 3101 489 81 globlastp 867 LNU7 walnuts|gb166|CV196459 3102 474 91.8 globlastp 868 LNU7 eucalyptus|gb166|CU394883 3103 474 90.3 globlastp 868 LNU27 eucalyptus|gb166|CU394883 3103 489 80 glotblastn 869 LNU7 grape|gb160|EC927944 3104 474 90.3 globlastp 870 LNU7 cleome_gynandra|10v1|SRR015532S0000915 3105 474 90.2 globlastp 871 LNU7 cleome_gynandra|10v1|SRR015532S0002395 3106 474 90.2 globlastp 872 LNU7 cleome_spinosa|10v1|SRR015531S0004899 3107 474 90.2 globlastp 873 LNU7 cleome_spinosa|10v1|SRR015531S0010059 3105 474 90.2 globlastp 874 LNU7 cleome_spinosa|10v1|SRR015531S0015400 3108 474 90.2 globlastp 875 LNU7 eggplant|10v1|FS005478 3109 474 90.2 globlastp 875 LNU27 eggplant|10v1|FS005478 3109 489 80 globlastp 876 LNU7 pepper|gb171|GD054049 3110 474 90.2 globlastp 876 LNU27 pepper|gb171|GD054049 3110 489 81.7 globlastp 877 LNU7 catharanthus|gb166|DT527689 3111 474 90.2 globlastp 878 LNU7 catharanthus|gb166|EG556443 3111 474 90.2 globlastp 879 LNU7 oak|gb170|SRR006309S0014100 3112 474 90.2 globlastp 880 LNU7 rice|gb170|OS01G19840 3113 474 90.2 globlastp 880 LNU27 rice|gb170|OS01G19840 3113 489 85 globlastp 881 LNU7 rice|gb170|OS05G28750 3113 474 90.2 globlastp 881 LNU27 rice|gb170|OS05G28750 3113 489 85 globlastp 882 LNU7 walnuts|gb166|EL900862 3114 474 90.2 globlastp 883 LNU7 citrus|gb166|BQ623885 3115 474 90.16 glotblastn 884 LNU7 amborella|gb166|CK759343 3116 474 88.7 globlastp 885 LNU7 avocado|10v1|CK767358 3117 474 88.7 globlastp 885 LNU27 avocado|10v1|CK767358 3117 489 80 glotblastn 886 LNU7 avocado|gb164|CK767358 3117 474 88.7 globlastp 886 LNU27 avocado|gb164|CK767358 3117 489 80 glotblastn 887 LNU7 nuphar|gb166|CV004221 3118 474 88.7 globlastp 888 LNU7 tomato|gb164|BG126482 3119 474 88.52 glotblastn 888 LNU27 tomato|gb164|BG126482 3119 489 80 glotblastn 889 LNU7 ipomoea_batatas|10v1|BU691209 3120 474 88.5 globlastp 890 LNU7 ipomoea_nil|10v1|BJ567189 3120 474 88.5 globlastp 891 LNU7 lotus|09v1|CRPLJ010213 3121 474 88.5 globlastp 892 LNU7 tomato|09v1|BG126482 3122 474 88.5 globlastp 892 LNU27 tomato|09v1|BG126482 3122 489 80 globlastp 893 LNU7 citrus|gb166|BQ624128 3123 474 88.5 globlastp 894 LNU7 ipomoea|gb157.2|BJ567189 3120 474 88.5 globlastp 895 LNU7 lettuce|gb157.2|DW044205 3124 474 88.5 globlastp 896 LNU7 lettuce|10v1|DW074561 3125 474 88.5 globlastp 897 LNU7 lettuce|gb157.2|DW074561 3125 474 88.5 globlastp 898 LNU7 lettuce|gb157.2|DW147214 3126 474 88.5 globlastp 899 LNU7 lovegrass|gb167|EH188904 3127 474 88.5 globlastp 899 LNU27 lovegrass|gb167|EH188904 3127 489 86.7 globlastp 900 LNU7 melon|gb165|AM723109 3128 474 88.5 globlastp 901 LNU7 melon|gb165|EB715608 3129 474 88.5 globlastp 902 LNU7 oak|gb170|DN950298 3130 474 88.5 globlastp 903 LNU7 potato|gb157.2|BQ047073 3122 474 88.5 globlastp 903 LNU27 potato|gb157.2|BQ047073 3122 489 80 globlastp 904 LNU7 sunflower|gb162|CD849282 3131 474 88.5 globlastp 905 LNU7 thellungiella|gb167|BI698609 3132 474 88.5 globlastp 906 LNU7 lettuce|10v1|DW044205 3124 474 88.5 globlastp 907 LNU7 arabidopsis_lyrata|09v1|JGIAL009087 3133 474 86.9 globlastp 908 LNU7 arabidopsis_lyrata|09v1|JGIAL013834 3134 474 86.9 globlastp 909 LNU7 canola|10v1|CD816913 3135 474 86.9 globlastp 910 LNU7 canola|10v1|CD838406 3135 474 86.9 globlastp 911 LNU7 canola|10v1|CN732166 3135 474 86.9 globlastp 912 LNU7 gerbera|09v1|AJ754854 3136 474 86.9 globlastp 913 LNU7 ginseng|10v1|AB042860 3137 474 86.9 globlastp 914 LNU7 millet|09v1|CD724720 3138 474 86.9 globlastp 914 LNU27 millet|09v1|CD724720 3138 489 85 globlastp 915 LNU7 salvia|10v1|SRR014553S0006508 3139 474 86.9 globlastp 916 LNU7 solanum_phureja|09v1|SPHBG126482 3140 474 86.9 globlastp 917 LNU7 sorghum|gb161.crp|AI664904 3141 474 86.9 globlastp 917 LNU27 sorghum|gb161.crp|AI664904 3141 489 85 globlastp 918 LNU7 arabidopsis|gb165|AT3G06680 3142 474 86.9 globlastp 919 LNU7 b_juncea|gb164|EVGN00263811010987 3135 474 86.9 globlastp 920 LNU7 b_juncea|gb164|EVGN00818312581324 3135 474 86.9 globlastp 921 LNU7 b_juncea|gb164|EVGN01551409763163 3135 474 86.9 globlastp 922 LNU7 b_juncea|gb164|EVGN01699912462188 3135 474 86.9 globlastp 923 LNU7 b_juncea|gb164|EVGN04088908911493 3143 474 86.9 globlastp 924 LNU7 b_oleracea|gb161|DY027316 3135 474 86.9 globlastp 925 LNU7 b_rapa|gb162|CX267004 3135 474 86.9 globlastp 926 LNU7 b_rapa|gb162|CX268468 3135 474 86.9 globlastp 927 LNU7 beet|gb162|BI096143 3144 474 86.9 globlastp 928 LNU7 canola|10v1|CD811781 3135 474 86.9 globlastp 929 LNU7 canola|gb161|CD811781 3135 474 86.9 globlastp 930 LNU7 canola|10v1|CD812329 3135 474 86.9 globlastp 931 LNU7 canola|gb161|CD812329 3135 474 86.9 globlastp 932 LNU7 canola|gb161|CD816913 3135 474 86.9 globlastp 933 LNU7 canola|gb161|CN732166 3135 474 86.9 globlastp 934 LNU7 canola|10v1|CX278337 3135 474 86.9 globlastp 935 LNU7 canola|gb161|CX278337 3135 474 86.9 globlastp 936 LNU7 cenchrus|gb166|EB653562 3138 474 86.9 globlastp 936 LNU27 cenchrus|gb166|EB653562 3138 489 85 globlastp 937 LNU7 coffea|10v1|DV679308 3145 474 86.9 globlastp 938 LNU7 coffea|gb157.2|DV679308 3145 474 86.9 globlastp 939 LNU7 dandelion|gb161|DY802911 3146 474 86.9 globlastp 940 LNU7 maize|gb170|AI941993 3147 474 86.9 globlastp 940 LNU27 maize|gb170|AI941993 3147 489 83.3 globlastp 941 LNU7 pepper|gb157.2|BM067951 3148 474 86.9 globlastp 941 LNU27 pepper|gb157.2|BM067951 3148 489 80 globlastp 942 LNU7 pepper|gb171|BM067951 3149 474 86.9 globlastp 942 LNU27 pepper|gb171|BM067951 3149 489 80 globlastp 943 LNU7 petunia|gb166|EB174600 3150 474 86.9 globlastp 944 LNU7 petunia|gb171|EB174600 3150 474 86.9 globlastp 945 LNU7 potato|gb157.2|BQ047370 3140 474 86.9 globlastp 946 LNU7 prunus|gb167|BI203148 3151 474 86.9 globlastp 947 LNU7 radish|gb164|EV527807 3134 474 86.9 globlastp 948 LNU7 radish|gb164|EV539631 3152 474 86.9 globlastp 949 LNU7 radish|gb164|EW732099 3135 474 86.9 globlastp 950 LNU7 radish|gb164|EW734121 3135 474 86.9 globlastp 951 LNU7 sorghum|09v1|SB09G017140 3141 474 86.9 globlastp 951 LNU27 sorghum|09v1|SB09G017140 3141 489 85 globlastp 952 LNU7 sorghum|09v1|SB09G017150 3153 474 86.9 globlastp 952 LNU27 sorghum|09v1|SB09G017150 3153 489 85 globlastp 953 LNU7 sorghum|gb161.crp|AW287208 3153 474 86.9 globlastp 953 LNU27 sorghum|gb161.crp|AW287208 3153 489 85 globlastp 954 LNU7 spurge|gb161|DV124618 3154 474 86.9 globlastp 955 LNU7 sugarcane|10v1|BQ530802 3141 474 86.9 globlastp 955 LNU27 sugarcane|10v1|BQ530802 3141 489 85 globlastp 956 LNU7 sugarcane|gb157.3|BQ530802 3141 474 86.9 globlastp 956 LNU27 sugarcane|gb157.3|BQ530802 3141 489 85 globlastp 957 LNU7 sugarcane|10v1|CA118622 3141 474 86.9 globlastp 957 LNU27 sugarcane|10v1|CA118622 3141 489 85 globlastp 958 LNU7 sugarcane|gb157.3|CA118622 3141 474 86.9 globlastp 958 LNU27 sugarcane|gb157.3|CA118622 3141 489 85 globlastp 959 LNU7 switchgrass|gb167|DN150845 3138 474 86.9 globlastp 959 LNU27 switchgrass|gb167|DN150845 3138 489 85 globlastp 960 LNU7 wheat|gb164|CD491023 3141 474 86.9 globlastp 960 LNU27 wheat|gb164|CD491023 3141 489 85 globlastp 961 LNU7 potato|10v1|BQ047073 3140 474 86.9 globlastp 962 LNU7 banana|gb167|DN239847 3155 474 85.5 globlastp 963 LNU7 banana|gb167|FL658741 3156 474 85.5 globlastp 964 LNU7 oil_palm|gb166|EL683904 3157 474 85.5 globlastp 965 LNU7 canola|10v1|BQ704618 3158 474 85.25 glotblastn 966 LNU7 dandelion|gb161|DY814075 3159 474 85.25 glotblastn 967 LNU7 b_nigra|09v1|GT069298 — 474 85.25 glotblastn 968 LNU7 petunia|gb171|CV300233 — 474 85.25 glotblastn 969 LNU7 thellungiella|gb167|BQ087680 — 474 85.25 glotblastn 970 LNU7 basilicum|10v1|DY323081 3160 474 85.2 globlastp 970 LNU27 basilicum|10v1|DY323081 3160 489 80.3 globlastp 971 LNU7 canola|10v1|CD811649 3161 474 85.2 globlastp 972 LNU7 cucumber|09v1|CK700790 3162 474 85.2 globlastp 973 LNU7 gerbera|09v1|AJ762109 3163 474 85.2 globlastp 974 LNU7 lotus|09v1|CRPLJ015426 3164 474 85.2 globlastp 975 LNU7 lotus|09v1|CRPLJ021029 3164 474 85.2 globlastp 976 LNU7 lotus|09v1|CRPLJ033772 3164 474 85.2 globlastp 977 LNU7 brachypodium|09v1|GT762410 3165 474 85.2 globlastp 977 LNU27 brachypodium|09v1|GT762410 3165 489 90 globlastp 978 LNU7 brachypodium|gb169|BE420561 3165 474 85.2 globlastp 978 LNU27 brachypodium|gb169|BE420561 3165 489 90 globlastp 979 LNU7 antirrhinum|gb166|AJ559707 3166 474 85.2 globlastp 980 LNU7 apple|gb157.3|CN444191 3167 474 85.2 globlastp 981 LNU7 apple|gb171|CN444191 3167 474 85.2 globlastp 982 LNU7 apple|gb157.3|CN489474 3167 474 85.2 globlastp 983 LNU7 apple|gb171|CN489474 3167 474 85.2 globlastp 984 LNU7 arabidopsis|gb165|AT3G06700 3168 474 85.2 globlastp 985 LNU7 artemisia|gb164|EY054666 3169 474 85.2 globlastp 986 LNU7 b_juncea|gb164|EVGN00375713871037P0 3170 474 85.2 globlastp 987 LNU7 b_juncea|gb164|EVGN01049614682128 3161 474 85.2 globlastp 988 LNU7 b_rapa|gb162|CV432967 3161 474 85.2 globlastp 989 LNU7 basilicum|gb157.3|DY323081 3160 474 85.2 globlastp 989 LNU27 basilicum|gb157.3|DY323081 3160 489 80.3 globlastp 990 LNU7 beech|gb170|SRR006293S0003253 3171 474 85.2 globlastp 991 LNU7 maize|gb170|AI600790 3172 474 85.2 globlastp 991 LNU27 maize|gb170|AI600790 3172 489 83.3 globlastp 992 LNU7 maize|gb170|AI833392 3173 474 85.2 globlastp 992 LNU27 maize|gb170|AI833392 3173 489 83.3 globlastp 993 LNU7 poplar|10v1|DT492219 3174 474 85.2 globlastp 994 LNU7 poplar|gb170|DT492219 3174 474 85.2 globlastp 995 LNU7 radish|gb164|EV536346 3170 474 85.2 globlastp 996 LNU7 radish|gb164|EV549950 3170 474 85.2 globlastp 997 LNU7 radish|gb164|EW714409 3170 474 85.2 globlastp 998 LNU7 radish|gb164|EX746273 3170 474 85.2 globlastp 999 LNU7 radish|gb164|FD556726 3170 474 85.2 globlastp 1000 LNU7 sunflower|gb162|CD846243 3175 474 85.2 globlastp 1001 LNU7 switchgrass|gb167|DN143529 3176 474 85.2 globlastp 1001 LNU27 switchgrass|gb167|DN143529 3176 489 83.3 globlastp 1002 LNU7 switchgrass|gb167|FL789549 3177 474 85.2 globlastp 1002 LNU27 switchgrass|gb167|FL789549 3177 489 83.3 globlastp 1003 LNU7 tamarix|gb166|CF198845 3178 474 85.2 globlastp 1004 LNU7 avocado|10v1|CK758909 3179 474 83.9 globlastp 1005 LNU7 avocado|gb164|CK758909 3179 474 83.9 globlastp 1006 LNU7 banana|gb167|FF559899 3180 474 83.9 globlastp 1007 LNU7 banana|gb167|FL661163 3181 474 83.9 globlastp 1008 LNU7 lovegrass|gb167|EH190358 3182 474 83.61 glotblastn 1008 LNU27 lovegrass|gb167|EH190358 3182 489 83.33 glotblastn 1009 LNU7 canola|10v1|DW998335 3183 474 83.6 globlastp 1010 LNU7 eggplant|10v1|FS009243 3184 474 83.6 globlastp 1011 LNU7 lettuce|10v1|DW101911 3185 474 83.6 globlastp 1012 LNU7 orobanche|10v1|SRR023189S0004367 3186 474 83.6 globlastp 1012 LNU27 orobanche|10v1|SRR023189S0004367 3186 489 80.3 globlastp 1013 LNU7 brachypodium|09v1|GT764657 3187 474 83.6 globlastp 1013 LNU27 brachypodium|09v1|GT764657 3187 489 88.3 globlastp 1014 LNU7 brachypodium|gb169|BE399643 3187 474 83.6 globlastp 1014 LNU27 brachypodium|gb169|BE399643 3187 489 88.3 globlastp 1015 LNU7 b_juncea|gb164|EVGN00222912251720 3188 474 83.6 globlastp 1016 LNU7 b_juncea|gb164|EVGN00516938790398 3189 474 83.6 globlastp 1017 LNU7 canola|10v1|CD839275 3190 474 83.6 globlastp 1018 LNU7 canola|gb161|CD811649 3190 474 83.6 globlastp 1019 LNU7 canola|gb161|H74817 3183 474 83.6 globlastp 1020 LNU7 lettuce|gb157.2|DW045025 3191 474 83.6 globlastp 1021 LNU7 lettuce|10v1|DW077777 3191 474 83.6 globlastp 1022 LNU7 lettuce|gb157.2|DW077777 3191 474 83.6 globlastp 1023 LNU7 lettuce|gb157.2|DW077988 3191 474 83.6 globlastp 1024 LNU7 lettuce|gb157.2|DW104130 3191 474 83.6 globlastp 1025 LNU7 maize|gb170|AI372387 3192 474 83.6 globlastp 1025 LNU27 maize|gb170|AI372387 3192 489 81.7 globlastp 1026 LNU7 poppy|gb166|FE964149 3193 474 83.6 globlastp 1027 LNU7 triphysaria|gb164|EX992128 3194 474 83.6 globlastp 1027 LNU27 triphysaria|gb164|EX992128 3194 489 83.3 globlastp 1028 LNU7 lettuce|10v1|DW045025 3191 474 83.6 globlastp 1029 LNU7 orobanche|10v1|SRR023495S0017698 3195 474 82.3 globlastp 1030 LNU7 tobacco|gb162|CV020926 3196 474 82.3 globlastp 1031 LNU7 liriodendron|gb166|CK757037 3197 474 82.3 globlastp 1032 LNU7 tobacco|gb162|BU673934 3195 474 82.3 globlastp 1033 LNU7 arabidopsis_lyrata|09v1|JGIAL017844 3198 474 82 globlastp 1034 LNU7 flax|09v1|EU829933 3199 474 82 globlastp 1035 LNU7 monkeyflower|10v1|DV206864 3200 474 82 globlastp 1036 LNU7 oat|10v1|GO582693 3201 474 82 globlastp 1036 LNU27 oat|10v1|GO582693 3201 489 93.3 globlastp 1037 LNU7 oat|10v1|GO582779 3201 474 82 globlastp 1037 LNU27 oat|10v1|GO582779 3201 489 93.3 globlastp 1038 LNU7 orobanche|10v1|SRR023189S0006077 3202 474 82 globlastp 1038 LNU27 orobanche|10v1|SRR023189S0006077 3202 489 80.3 globlastp 1039 LNU7 b_juncea|gb164|EVGN04206719550893 3203 474 82 globlastp 1040 LNU7 cacao|gb167|CU480546 3204 474 82 globlastp 1041 LNU7 dandelion|gb161|DY808273 3205 474 82 globlastp 1042 LNU7 dandelion|gb161|DY811268 3205 474 82 globlastp 1043 LNU7 dandelion|gb161|DY814721 3205 474 82 globlastp 1044 LNU7 lettuce|gb157.2|DW101911 3206 474 82 globlastp 1045 LNU7 rose|10v1|BQ105463 3207 474 82 globlastp 1046 LNU7 rose|gb157.2|BQ105463 3207 474 82 globlastp 1047 LNU7 sunflower|gb162|DY905617 3205 474 82 globlastp 1048 LNU7 switchgrass|gb167|DN150598 3208 474 82 globlastp 1048 LNU27 switchgrass|gb167|DN150598 3208 489 81.7 globlastp 1049 LNU7 cichorium|gb171|FL680147 3209 474 81.97 glotblastn 1050 LNU7 cycas|gb166|CB093385 3210 474 81.5 globlastp 1051 LNU7 strawberry|gb164|CO380923 3211 474 81 globlastp 1052 LNU7 tobacco|gb162|CV019192 3212 474 80.6 globlastp 1053 LNU7 ipomoea_batatas|10v1|DV037499XX2 3213 474 80.33 glotblastn 1054 LNU7 lotus|09v1|BW596153 3214 474 80.33 glotblastn 1055 LNU7 lotus|gb157.2|BP059519 3215 474 80.33 glotblastn 1056 LNU7 monkeyflower|10v1|CV521685 3216 474 80.3 globlastp 1057 LNU7 solanum_phureja|09v1|SPHAF204786 3217 474 80.3 globlastp 1058 LNU7 potato|10v1|BQ512966 3217 474 80.3 globlastp 1059 LNU7 potato|gb157.2|BQ512966 3217 474 80.3 globlastp 1060 LNU7 tobacco|gb162|BP530058 3218 474 80.3 globlastp 1061 LNU7 tomato|09v1|AF204786 3219 474 80.3 globlastp 1062 LNU7 tomato|gb164|AF204786 3219 474 80.3 globlastp 1063 LNU7 cryptomeria|gb166|BW992620 3220 474 80 globlastp 1064 LNU8 arabidopsis_lyrata|09v1|JGIAL010354 3221 475 93.6 globlastp 1065 LNU9 rice|gb170|OS07G37280 3222 476 87.84 glotblastn 1066 LNU13 sorghum|09v1|SB02G036230 3223 480 81.8 globlastp 1067 LNU13 sorghum|gb161.crp|BQ635805 3223 480 81.8 globlastp 1068 LNU13 maize|gb170|BI245385 3224 480 80.7 globlastp 1069 LNU14 arabidopsis_lyrata|09v1|JGIAL015001 3225 481 96.3 globlastp 1070 LNU15 arabidopsis_lyrata|09v1|JGIAL009168 3226 482 94.2 globlastp 1071 LNU17 sorghum|09v1|SB03G011640 3227 483 84.6 globlastp 1072 LNU17 sorghum|gb161.crp|AI947401 3227 483 84.6 globlastp 1073 LNU17 millet|09v1|EVO454PM011107 3228 483 84.1 globlastp 1074 LNU17 sugarcane|gb157.3|CA114497 3229 483 84.1 globlastp 1075 LNU17 switchgrass|gb167|DN142702 3230 483 82.5 globlastp 1076 LNU17 maize|gb170|AI861546 3231 483 81.2 globlastp 1077 LNU17 brachypodium|09v1|GT758222 3232 483 80.5 globlastp 1078 LNU17 brachypodium|gb169|BQ246612 3232 483 80.5 globlastp 1079 LNU19 maize|gb170|DR806345 3233 484 82.6 globlastp 1080 LNU19 sorghum|gb161.crp|AW679176 3234 484 80.5 globlastp 1081 LNU20 potato|gb157.2|BG888517 3235 485 97.8 globlastp 1082 LNU20 potato|10v1|BG888517 3236 485 97.6 globlastp 1083 LNU20 solanum_phureja|09v1|SPHBG131270 3237 485 97.4 globlastp 1084 LNU20 pepper|gb171|BM062238 3238 485 89.5 globlastp 1085 LNU20 tobacco|gb162|EB428440 3239 485 83.74 glotblastn 1086 LNU23 arabidopsis_lyrata|09v1|JGIAL002476 3240 486 93.2 globlastp 1087 LNU23 radish|gb164|EW732145 3241 486 88.5 globlastp 1088 LNU24 arabidopsis_lyrata|09v1|JGIAL003443 3242 487 98.2 globlastp 1089 LNU24 radish|gb164|EV528988 3243 487 87 globlastp 1090 LNU24 arabidopsis|gb165|AT1G33090 3244 487 85.8 globlastp 1091 LNU24 arabidopsis|gb165|AT1G33100 3245 487 85.2 globlastp 1092 LNU24 arabidopsis_lyrata|09v1|JGIAL003442 3246 487 85 globlastp 1093 LNU24 arabidopsis|gb165|AT1G33080 3247 487 83.2 globlastp 1094 LNU25 sugarcane|10v1|BQ533886 3248 488 96.1 globlastp 1095 LNU25 sugarcane|gb157.3|BQ533886 3249 488 96.1 globlastp 1096 LNU25 maize|gb170|AW563076 3250 488 93.6 globlastp 1097 LNU25 switchgrass|gb167|FL773555 3251 488 83.3 globlastp 1098 LNU27 wheat|gb164|BE399643 489 489 100 globlastp 1099 LNU27 wheat|gb164|BE424751 489 489 100 globlastp 1100 LNU27 wheat|gb164|BE443944 489 489 100 globlastp 1101 LNU27 rye|gb164|BG263912 3252 489 96.7 globlastp 1102 LNU27 fescue|gb161|CK803089 3253 489 85 globlastp 1103 LNU28 wheat|gb164|BF293133 3254 490 97.1 globlastp 1104 LNU28 pseudoroegneria|gb167|FF346547 3255 490 96 globlastp 1105 LNU28 wheat|gb164|CA655539 3256 490 95.7 globlastp 1106 LNU28 leymus|gb166|EG382149 3257 490 95.5 globlastp 1107 LNU28 brachypodium|09v1|GT829440 3258 490 85.2 globlastp 1108 LNU28 brachypodium|gb169|BF293133 3258 490 85.2 globlastp 1109 LNU29 solanum_phureja|09v1|SPHAI487919 3259 491 91.2 globlastp 1110 LNU29 potato|gb157.2|BM405532 3260 491 88.33 glotblastn 1111 LNU32 sugarcane|10v1|CA070626 3261 492 91.12 glotblastn 1112 LNU32 sugarcane|gb157.3|CA070626 3262 492 87 globlastp 1113 LNU32 sorghum|09v1|SB08G001710 3263 492 85.1 globlastp 1114 LNU32 sorghum|gb161.crp|CD463367 3263 492 85.1 globlastp 1115 LNU32 maize|gb170|CB604763 3264 492 84.8 globlastp 1116 LNU32 maize|gb170|BE552794 3265 492 83.3 globlastp 1117 LNU32 switchgrass|gb167|DN144499 3266 492 82.6 globlastp 1118 LNU33 soybean|gb168|BQ124735 3267 493 92.95 glotblastn 1119 LNU33 lotus|09v1|AV776761 3268 493 80.6 globlastp 1120 LNU34 sorghum|09v1|SB03G034160 3269 494 87.86 glotblastn 1121 LNU34 sorghum|gb161.crp|DN212069 3270 494 87.86 glotblastn 1122 LNU34 brachypodium|09v1|GT773303 3271 494 86.43 glotblastn 1123 LNU34 wheat|gb164|BG608344 3272 494 85.71 glotblastn 1124 LNU34 maize|gb170|BE344718 3273 494 85.2 globlastp 1125 LNU36 soybean|gb168|BE823007 3274 496 94.3 globlastp 1126 LNU36 soybean|gb168|CD398253 3275 496 80.7 globlastp 1127 LNU43 soybean|gb168|AI967672 3276 499 94.9 globlastp 1128 LNU43 bean|gb167|CA896732 3277 499 90.4 globlastp 1129 LNU43 liquorice|gb171|FS261351 3278 499 89.9 globlastp 1130 LNU43 cowpea|gb166|FF399439 3279 499 89.3 globlastp 1131 LNU43 peanut|gb171|ES721626 3280 499 88 globlastp 1132 LNU43 peanut|gb167|EE125486 3281 499 87 globlastp 1133 LNU43 peanut|gb171|EE125486 3281 499 87 globlastp 1134 LNU43 lotus|09v1|LLAI967672 3282 499 84.9 globlastp 1135 LNU43 lotus|gb157.2|AI967672 3282 499 84.9 globlastp 1136 LNU43 chickpea|09v2|FE669917 3283 499 84.8 globlastp 1137 LNU43 pea|09v1|GFXPEAATPASEX1 3284 499 81.3 globlastp 1138 LNU44 pigeonpea|gb171|GR464245 3285 500 94.9 globlastp 1139 LNU44 cowpea|gb166|FC459300 3286 500 92.4 globlastp 1140 LNU44 liquorice|gb171|FS238932 3287 500 89.9 globlastp 1141 LNU44 bean|gb167|CB539787 3288 500 87.34 glotblastn 1142 LNU44 bean|gb167|CA899920 3289 500 86.1 globlastp 1143 LNU44 lotus|09v1|LLCN825274 3290 500 86.1 globlastp 1144 LNU44 lotus|gb157.2|CN825274 3290 500 86.1 globlastp 1145 LNU44 soybean|gb168|BQ155489 3291 500 84.7 globlastp 1146 LNU44 bean|gb167|FD799417 3292 500 83.5 globlastp 1147 LNU44 medicago|09v1|AW171675 3293 500 83.5 globlastp 1148 LNU44 medicago|gb157.2|AW171675 3293 500 83.5 globlastp 1149 LNU44 peanut|gb167|CD038813 3294 500 81.2 globlastp 1150 LNU44 peanut|gb171|CD038813 3294 500 81.2 globlastp 1151 LNU44 peanut|gb171|CD038024 3295 500 80 globlastp 1152 LNU45 chickpea|09v2|GR406612 501 501 100 globlastp 1153 LNU45 liquorice|gb171|FS238653 501 501 100 globlastp 1154 LNU45 pea|09v1|AM161941 501 501 100 globlastp 1155 LNU45 pigeonpea|gb171|GR465032 501 501 100 globlastp 1156 LNU45 bean|gb167|CA897298 501 501 100 globlastp 1157 LNU45 chestnut|gb170|SRR006295S0059092 501 501 100 globlastp 1158 LNU45 cowpea|gb166|DR068382 501 501 100 globlastp 1159 LNU45 cowpea|gb166|EG594283 501 501 100 globlastp 1160 LNU45 cowpea|gb166|FC456876 501 501 100 globlastp 1161 LNU45 lotus|09v1|BI419054 501 501 100 globlastp 1162 LNU45 lotus|gb157.2|BI419054 501 501 100 globlastp 1163 LNU45 lotus|09v1|LLCB829590 501 501 100 globlastp 1164 LNU45 lotus|gb157.2|CB829590 501 501 100 globlastp 1165 LNU45 medicago|09v1|BE318806 501 501 100 globlastp 1166 LNU45 medicago|gb157.2|BE318806 501 501 100 globlastp 1167 LNU45 oak|gb170|CR627523 501 501 100 globlastp 1168 LNU45 peanut|gb167|CD037890 501 501 100 globlastp 1169 LNU45 peanut|gb171|CD037890 501 501 100 globlastp 1170 LNU45 peanut|gb171|CD038469 501 501 100 globlastp 1171 LNU45 peanut|gb167|EE126116 501 501 100 globlastp 1172 LNU45 peanut|gb171|EE126116 501 501 100 globlastp 1173 LNU45 peanut|gb167|EE126336 501 501 100 globlastp 1174 LNU45 peanut|gb171|EE126336 501 501 100 globlastp 1175 LNU45 chickpea|09v2|GR392190 3296 501 98.8 globlastp 1176 LNU45 chickpea|09v2|GR392639 3297 501 98.8 globlastp 1177 LNU45 cleome_gynandra|10v1|SRR015532S0009070 3296 501 98.8 globlastp 1178 LNU45 cucumber|09v1|CK086106 3298 501 98.8 globlastp 1179 LNU45 heritiera|10v1|SRR005795S0009553 3299 501 98.8 globlastp 1180 LNU45 heritiera|10v1|SRR005795S0022077 3299 501 98.8 globlastp 1181 LNU45 liquorice|gb171|FS245788 3300 501 98.8 globlastp 1182 LNU45 bean|gb167|CA897297 3300 501 98.8 globlastp 1183 LNU45 beech|gb170|SRR006293S0000924 3298 501 98.8 globlastp 1184 LNU45 cacao|gb167|CU473827 3299 501 98.8 globlastp 1185 LNU45 cassava|gb164|DV442696 3298 501 98.8 globlastp 1186 LNU45 castorbean|09v1|EE256323 3298 501 98.8 globlastp 1187 LNU45 castorbean|gb160|EE256323 3298 501 98.8 globlastp 1188 LNU45 castorbean|09v1|GE636711 3298 501 98.8 globlastp 1189 LNU45 chestnut|gb170|SRR006295S0001785 3298 501 98.8 globlastp 1190 LNU45 cotton|gb164|BE052927 3299 501 98.8 globlastp 1191 LNU45 cotton|gb164|BE053779 3299 501 98.8 globlastp 1192 LNU45 cotton|gb164|BE054840 3299 501 98.8 globlastp 1193 LNU45 cotton|gb164|BF275747 3299 501 98.8 globlastp 1194 LNU45 cotton|gb164|BG444626 3299 501 98.8 globlastp 1195 LNU45 cotton|gb164|CO104281 3299 501 98.8 globlastp 1196 LNU45 cowpea|gb166|FC460219 3300 501 98.8 globlastp 1197 LNU45 eucalyptus|gb166|CB967805 3298 501 98.8 globlastp 1198 LNU45 eucalyptus|gb166|CT980235 3298 501 98.8 globlastp 1199 LNU45 medicago|gb157.2|AW329579 3296 501 98.8 globlastp 1200 LNU45 medicago|09v1|LLBE239494 3296 501 98.8 globlastp 1201 LNU45 medicago|gb157.2|BE239494 3296 501 98.8 globlastp 1202 LNU45 melon|gb165|EB714819 3298 501 98.8 globlastp 1203 LNU45 oak|gb170|DN950003 3298 501 98.8 globlastp 1204 LNU45 peanut|gb167|EH046888 3301 501 98.8 globlastp 1205 LNU45 peanut|gb171|EH046888 3301 501 98.8 globlastp 1206 LNU45 rose|10v1|BQ104562 3302 501 98.8 globlastp 1207 LNU45 soybean|gb168|BM140026 3300 501 98.8 globlastp 1208 LNU45 spurge|gb161|BE095304 3298 501 98.8 globlastp 1209 LNU45 cleome_spinosa|10v1|GR931938 3303 501 97.7 globlastp 1210 LNU45 cleome_spinosa|10v1|SRR015531S0016648 3303 501 97.7 globlastp 1211 LNU45 cleome_spinosa|10v1|SRR015531S0024494 3303 501 97.7 globlastp 1212 LNU45 cleome_spinosa|10v1|SRR015531S0039098 3303 501 97.7 globlastp 1213 LNU45 cucumber|09v1|AM715462 3304 501 97.7 globlastp 1214 LNU45 lettuce|10v1|DW075415 3305 501 97.7 globlastp 1215 LNU45 liquorice|gb171|FS239649 3306 501 97.7 globlastp 1216 LNU45 monkeyflower|10v1|CV519036 3307 501 97.7 globlastp 1217 LNU45 pea|09v1|EX570516 3308 501 97.7 globlastp 1218 LNU45 pea|09v1|EX571249 3309 501 97.7 globlastp 1219 LNU45 tea|10v1|CV013950 3310 501 97.7 globlastp 1220 LNU45 antirrhinum|gb166|AJ558887 3311 501 97.7 globlastp 1221 LNU45 beet|gb162|BQ592037 3312 501 97.7 globlastp 1222 LNU45 bruguiera|gb166|BP941557 3313 501 97.7 globlastp 1223 LNU45 cacao|gb167|CF974299 3314 501 97.7 globlastp 1224 LNU45 cacao|gb167|CU476326 3315 501 97.7 globlastp 1225 LNU45 cassava|09v1|BI325193 3316 501 97.7 globlastp 1226 LNU45 cassava|gb164|BI325193 3316 501 97.7 globlastp 1227 LNU45 cassava|09v1|CK644610 3317 501 97.7 globlastp 1228 LNU45 cassava|gb164|CK644610 3317 501 97.7 globlastp 1229 LNU45 cassava|09v1|DV442696 3317 501 97.7 globlastp 1230 LNU45 castorbean|gb160|MDL30128M008573 3318 501 97.7 globlastp 1231 LNU45 cycas|gb166|CB091386 3319 501 97.7 globlastp 1232 LNU45 cycas|gb166|CB092866 3319 501 97.7 globlastp 1233 LNU45 grape|gb160|EC932417 3320 501 97.7 globlastp 1234 LNU45 iceplant|gb164|BE034168 3321 501 97.7 globlastp 1235 LNU45 lettuce|gb157.2|DW075415 3305 501 97.7 globlastp 1236 LNU45 lettuce|gb157.2|DW103341 3305 501 97.7 globlastp 1237 LNU45 lettuce|gb157.2|DW145378 3305 501 97.7 globlastp 1238 LNU45 prunus|gb167|CB821790 3322 501 97.7 globlastp 1239 LNU45 rose|gb157.2|BQ104562 3323 501 97.7 globlastp 1240 LNU45 spurge|gb161|DV133006 3324 501 97.7 globlastp 1241 LNU45 strawberry|gb164|CO379162 3325 501 97.7 globlastp 1242 LNU45 tamarix|gb166|CN605485 3312 501 97.7 globlastp 1243 LNU45 walnuts|gb166|CV197870 3312 501 97.7 globlastp 1244 LNU45 zamia|gb166|DY034316 3319 501 97.7 globlastp 1245 LNU45 canola|10v1|CD817525 3326 501 96.51 glotblastn 1246 LNU45 blueberry|10v1|CF811404 3327 501 96.5 globlastp 1247 LNU45 canola|10v1|CD839015 3328 501 96.5 globlastp 1248 LNU45 canola|10v1|CN731675 3328 501 96.5 globlastp 1249 LNU45 canola|10v1|EE476478 3328 501 96.5 globlastp 1250 LNU45 cleome_gynandra|10v1|SRR015532S0012040 3329 501 96.5 globlastp 1251 LNU45 flax|09v1|EU829812 3330 501 96.5 globlastp 1252 LNU45 gerbera|09v1|AJ761450 3331 501 96.5 globlastp 1253 LNU45 ipomoea_nil|10v1|BJ554792 3332 501 96.5 globlastp 1254 LNU45 ipomoea_nil|10v1|BJ559906 3332 501 96.5 globlastp 1255 LNU45 ipomoea_nil|10v1|CJ742456 3332 501 96.5 globlastp 1256 LNU45 monkeyflower|10v1|DV212640 3333 501 96.5 globlastp 1257 LNU45 salvia|10v1|CV164158 3333 501 96.5 globlastp 1258 LNU45 salvia|10v1|CV165453 3333 501 96.5 globlastp 1259 LNU45 amborella|gb166|FD437556 3334 501 96.5 globlastp 1260 LNU45 antirrhinum|gb166|AJ560227 3335 501 96.5 globlastp 1261 LNU45 apple|gb157.3|CN492050 3336 501 96.5 globlastp 1262 LNU45 apple|gb171|CN492050 3336 501 96.5 globlastp 1263 LNU45 apple|gb157.3|CN997325 3336 501 96.5 globlastp 1264 LNU45 apple|gb171|CN997325 3336 501 96.5 globlastp 1265 LNU45 b_juncea|gb164|EVGN00032311610584 3328 501 96.5 globlastp 1266 LNU45 b_juncea|gb164|EVGN00163218130726 3328 501 96.5 globlastp 1267 LNU45 b_juncea|gb164|EVGN00242617670457 3328 501 96.5 globlastp 1268 LNU45 b_juncea|gb164|EVGN00404524182700 3328 501 96.5 globlastp 1269 LNU45 b_juncea|gb164|EVGN00541511341883 3328 501 96.5 globlastp 1270 LNU45 b_juncea|gb164|EVGN00673809061646 3328 501 96.5 globlastp 1271 LNU45 b_juncea|gb164|EVGN00683412381058 3328 501 96.5 globlastp 1272 LNU45 b_juncea|gb164|EVGN01161211992680 3328 501 96.5 globlastp 1273 LNU45 b_juncea|gb164|EVGN01304909632819 3328 501 96.5 globlastp 1274 LNU45 b_juncea|gb164|EVGN04290618070322 3328 501 96.5 globlastp 1275 LNU45 b_oleracea|gb161|AM062107 3328 501 96.5 globlastp 1276 LNU45 b_oleracea|gb161|DY027039 3328 501 96.5 globlastp 1277 LNU45 b_oleracea|gb161|DY027348 3328 501 96.5 globlastp 1278 LNU45 b_oleracea|gb161|DY027603 3328 501 96.5 globlastp 1279 LNU45 b_oleracea|gb161|DY029297 3328 501 96.5 globlastp 1280 LNU45 b_rapa|gb162|BG544410 3328 501 96.5 globlastp 1281 LNU45 b_rapa|gb162|CA992030 3328 501 96.5 globlastp 1282 LNU45 b_rapa|gb162|CV432516 3328 501 96.5 globlastp 1283 LNU45 b_rapa|gb162|CV433072 3328 501 96.5 globlastp 1284 LNU45 b_rapa|gb162|CX266536 3328 501 96.5 globlastp 1285 LNU45 b_rapa|gb162|CX268525 3328 501 96.5 globlastp 1286 LNU45 b_rapa|gb162|CX270594 3328 501 96.5 globlastp 1287 LNU45 b_rapa|gb162|CX273157 3328 501 96.5 globlastp 1288 LNU45 b_rapa|gb162|EE530283 3328 501 96.5 globlastp 1289 LNU45 bruguiera|gb166|BP948881 3337 501 96.5 globlastp 1290 LNU45 canola|gb161|CD812378 3328 501 96.5 globlastp 1291 LNU45 canola|gb161|CD812394 3328 501 96.5 globlastp 1292 LNU45 canola|10v1|CD812830 3328 501 96.5 globlastp 1293 LNU45 canola|gb161|CD812830 3328 501 96.5 globlastp 1294 LNU45 canola|gb161|CD812870 3328 501 96.5 globlastp 1295 LNU45 canola|gb161|CD817916 3328 501 96.5 globlastp 1296 LNU45 canola|10v1|CD818245 3328 501 96.5 globlastp 1297 LNU45 canola|gb161|CD818245 3328 501 96.5 globlastp 1298 LNU45 canola|gb161|CD818496 3328 501 96.5 globlastp 1299 LNU45 canola|gb161|CD821364 3328 501 96.5 globlastp 1300 LNU45 canola|gb161|CD834560 3328 501 96.5 globlastp 1301 LNU45 canola|gb161|CN731675 3328 501 96.5 globlastp 1302 LNU45 canola|gb161|EE476478 3328 501 96.5 globlastp 1303 LNU45 centaurea|gb166|EH740133 3338 501 96.5 globlastp 1304 LNU45 centaurea|gb166|EH744958 3338 501 96.5 globlastp 1305 LNU45 centaurea|gb166|EH785564 3331 501 96.5 globlastp 1306 LNU45 citrus|gb166|BQ624315 3339 501 96.5 globlastp 1307 LNU45 citrus|gb166|BQ624832 3339 501 96.5 globlastp 1308 LNU45 clover|gb162|BB930040 3340 501 96.5 globlastp 1309 LNU45 cryptomeria|gb166|BP174475 3341 501 96.5 globlastp 1310 LNU45 cynara|gb167|GE585914 3331 501 96.5 globlastp 1311 LNU45 ginger|gb164|DY349602 3342 501 96.5 globlastp 1312 LNU45 grape|gb160|BE846411 3343 501 96.5 globlastp 1313 LNU45 ipomoea|gb157.2|CJ741047 3332 501 96.5 globlastp 1314 LNU45 ipomoea|gb157.2|CJ742456 3332 501 96.5 globlastp 1315 LNU45 lettuce|10v1|DW044163 3331 501 96.5 globlastp 1316 LNU45 lettuce|gb157.2|DW044163 3331 501 96.5 globlastp 1317 LNU45 lettuce|gb157.2|DW045774 3331 501 96.5 globlastp 1318 LNU45 lettuce|gb157.2|DW103758 3331 501 96.5 globlastp 1319 LNU45 lettuce|gb157.2|DW105810 3331 501 96.5 globlastp 1320 LNU45 melon|gb165|AM715462 3344 501 96.5 globlastp 1321 LNU45 nuphar|gb166|CD474984 3345 501 96.5 globlastp 1322 LNU45 oil_palm|gb166|EL684405 3346 501 96.5 globlastp 1323 LNU45 oil_palm|gb166|EY413173 3342 501 96.5 globlastp 1324 LNU45 papaya|gb165|AM903803 3347 501 96.5 globlastp 1325 LNU45 papaya|gb165|EX239749 3348 501 96.5 globlastp 1326 LNU45 pine|10v1|AI812758 3349 501 96.5 globlastp 1327 LNU45 pine|gb157.2|AI812758 3349 501 96.5 globlastp 1328 LNU45 poplar|10v1|AI165443 3350 501 96.5 globlastp 1329 LNU45 poplar|gb170|AI165443 3350 501 96.5 globlastp 1330 LNU45 poplar|10v1|BI070097 3350 501 96.5 globlastp 1331 LNU45 poplar|gb170|BI070097 3350 501 96.5 globlastp 1332 LNU45 poplar|10v1|BI119656 3350 501 96.5 globlastp 1333 LNU45 poplar|gb170|BI119656 3350 501 96.5 globlastp 1334 LNU45 prunus|gb167|BU039142 3351 501 96.5 globlastp 1335 LNU45 radish|gb164|EV525442 3328 501 96.5 globlastp 1336 LNU45 radish|gb164|EV527675 3328 501 96.5 globlastp 1337 LNU45 radish|gb164|EV536763 3328 501 96.5 globlastp 1338 LNU45 radish|gb164|EV537524 3328 501 96.5 globlastp 1339 LNU45 radish|gb164|EW723868 3328 501 96.5 globlastp 1340 LNU45 radish|gb164|EW725365 3328 501 96.5 globlastp 1341 LNU45 radish|gb164|EW733186 3328 501 96.5 globlastp 1342 LNU45 radish|gb164|EW734391 3328 501 96.5 globlastp 1343 LNU45 radish|gb164|EX757217 3328 501 96.5 globlastp 1344 LNU45 radish|gb164|EX765397 3328 501 96.5 globlastp 1345 LNU45 radish|gb164|EX895252 3328 501 96.5 globlastp 1346 LNU45 radish|gb164|EY905533 3328 501 96.5 globlastp 1347 LNU45 radish|gb164|EY934770 3328 501 96.5 globlastp 1348 LNU45 spruce|gb162|CO227497 3349 501 96.5 globlastp 1349 LNU45 strawberry|gb164|CO379638 3352 501 96.5 globlastp 1350 LNU45 sunflower|gb162|CD849156 3331 501 96.5 globlastp 1351 LNU45 sunflower|gb162|CD849309 3331 501 96.5 globlastp 1352 LNU45 triphysaria|gb164|EX989107 3333 501 96.5 globlastp 1353 LNU45 triphysaria|gb164|EY001721 3333 501 96.5 globlastp 1354 LNU45 zamia|gb166|DY036444 3353 501 96.5 globlastp 1355 LNU45 lettuce|10v1|DW045774 3331 501 96.5 globlastp 1356 LNU45 lettuce|10v1|DW099098 3331 501 96.5 globlastp 1357 LNU45 canola|10v1|CD812870 3328 501 96.5 globlastp 1358 LNU45 canola|10v1|CD812378 3328 501 96.5 globlastp 1359 LNU45 canola|10v1|CD834560 3328 501 96.5 globlastp 1360 LNU45 salvia|10v1|SRR014553S0002286 3354 501 95.35 glotblastn 1361 LNU45 b_juncea|gb164|EVGN00337914530877 3355 501 95.35 glotblastn 1362 LNU45 canola|gb161|EL590902 3356 501 95.35 glotblastn 1363 LNU45 citrus|gb166|CF503931 3357 501 95.35 glotblastn 1364 LNU45 safflower|gb162|EL403359 3358 501 95.35 glotblastn 1365 LNU45 arabidopsis_lyrata|09v1|JGIAL029003 3359 501 95.3 globlastp 1366 LNU45 avocado|10v1|FD506790 3360 501 95.3 globlastp 1367 LNU45 cichorium|gb171|EH702627 3361 501 95.3 globlastp 1368 LNU45 eggplant|10v1|FS000719 3362 501 95.3 globlastp 1369 LNU45 potato|10v1|BG589651 3363 501 95.3 globlastp 1370 LNU45 salvia|10v1|SRR014553S0005980 3364 501 95.3 globlastp 1371 LNU45 apple|gb171|CN490097 3365 501 95.3 globlastp 1372 LNU45 arabidopsis|gb165|AT3G61110 3366 501 95.3 globlastp 1373 LNU45 artemisia|gb164|EY036326 3367 501 95.3 globlastp 1374 LNU45 artemisia|gb164|EY037581 3367 501 95.3 globlastp 1375 LNU45 avocado|10v1|CK754126 3368 501 95.3 globlastp 1376 LNU45 avocado|gb164|CK754126 3368 501 95.3 globlastp 1377 LNU45 banana|gb167|ES435098 3369 501 95.3 globlastp 1378 LNU45 banana|gb167|FF560357 3370 501 95.3 globlastp 1379 LNU45 banana|gb167|FF562322 3371 501 95.3 globlastp 1380 LNU45 canola|10v1|EE455490 3372 501 95.3 globlastp 1381 LNU45 canola|gb161|EE455490 3372 501 95.3 globlastp 1382 LNU45 catharanthus|gb166|EG561174 3373 501 95.3 globlastp 1383 LNU45 catharanthus|gb166|FD415347 3373 501 95.3 globlastp 1384 LNU45 cichorium|gb166|DT213797 3361 501 95.3 globlastp 1385 LNU45 cichorium|gb171|DT213797 3361 501 95.3 globlastp 1386 LNU45 citrus|gb166|CX640799 3374 501 95.3 globlastp 1387 LNU45 cryptomeria|gb166|BP174101 3375 501 95.3 globlastp 1388 LNU45 cynara|gb167|GE585853 3376 501 95.3 globlastp 1389 LNU45 ginger|gb164|DY351710 3377 501 95.3 globlastp 1390 LNU45 ginger|gb164|DY358500 3377 501 95.3 globlastp 1391 LNU45 ginger|gb164|DY367611 3378 501 95.3 globlastp 1392 LNU45 ipomoea|gb157.2|BJ554792 3379 501 95.3 globlastp 1393 LNU45 kiwi|gb166|FG410222 3380 501 95.3 globlastp 1394 LNU45 kiwi|gb166|FG430714 3380 501 95.3 globlastp 1395 LNU45 kiwi|gb166|FG441586 3380 501 95.3 globlastp 1396 LNU45 kiwi|gb166|FG461878 3380 501 95.3 globlastp 1397 LNU45 lettuce|10v1|DW077971 3379 501 95.3 globlastp 1398 LNU45 lettuce|gb157.2|DW077971 3379 501 95.3 globlastp 1399 LNU45 liriodendron|gb166|CO999247 3377 501 95.3 globlastp 1400 LNU45 liriodendron|gb166|FD495039 3377 501 95.3 globlastp 1401 LNU45 nicotiana_benthamiana|gb162| 3367 501 95.3 globlastp CN744078 1402 LNU45 oil_palm|gb166|EL681535 3381 501 95.3 globlastp 1403 LNU45 oil_palm|gb166|EL684385 3377 501 95.3 globlastp 1404 LNU45 pepper|gb157.2|CA514595 3362 501 95.3 globlastp 1405 LNU45 pepper|gb171|CA514595 3362 501 95.3 globlastp 1406 LNU45 pine|gb157.2|AA739876 3382 501 95.3 globlastp 1407 LNU45 pine|gb157.2|AI812974 3382 501 95.3 globlastp 1408 LNU45 pine|gb157.2|AL749664 3382 501 95.3 globlastp 1409 LNU45 potato|gb157.2|BE923191 3363 501 95.3 globlastp 1410 LNU45 potato|gb157.2|BF153777 3363 501 95.3 globlastp 1411 LNU45 potato|gb157.2|BG589651 3363 501 95.3 globlastp 1412 LNU45 potato|gb157.2|BM406913 3363 501 95.3 globlastp 1413 LNU45 radish|gb164|EV535745 3383 501 95.3 globlastp 1414 LNU45 rose|10v1|BQ106521 3384 501 95.3 globlastp 1415 LNU45 sesame|gb157.2|BU668222 3385 501 95.3 globlastp 1416 LNU45 spruce|gb162|CO217320 3382 501 95.3 globlastp 1417 LNU45 sunflower|gb162|CD849221 3386 501 95.3 globlastp 1418 LNU45 sunflower|gb162|CD851828 3387 501 95.3 globlastp 1419 LNU45 sunflower|gb162|DY954225 3386 501 95.3 globlastp 1420 LNU45 thellungiella|gb167|BM985525 3372 501 95.3 globlastp 1421 LNU45 tobacco|gb162|CV016291 3367 501 95.3 globlastp 1422 LNU45 tobacco|gb162|CV018253 3367 501 95.3 globlastp 1423 LNU45 tomato|gb164|BG124194 3362 501 95.3 globlastp 1424 LNU45 tomato|gb164|BG126885 3362 501 95.3 globlastp 1425 LNU45 tomato|gb164|BG134762 3362 501 95.3 globlastp 1426 LNU45 pine|10v1|AA739876 3382 501 95.3 globlastp 1427 LNU45 potato|10v1|AJ489106 3363 501 95.3 globlastp 1428 LNU45 potato|10v1|BM406913 3363 501 95.3 globlastp 1429 LNU45 tomato|09v1|BG124194 3362 501 95.3 globlastp 1430 LNU45 arabidopsis_lyrata|09v1|BQ834271 3388 501 94.2 globlastp 1431 LNU45 arabidopsis_lyrata|09v1|JGIAL015965 3389 501 94.2 globlastp 1432 LNU45 ipomoea_batatas|10v1|CB330065 3390 501 94.2 globlastp 1433 LNU45 ipomoea_batatas|10v1|CB330743 3391 501 94.2 globlastp 1434 LNU45 ipomoea_batatas|10v1|CO500840 3392 501 94.2 globlastp 1435 LNU45 monkeyflower|10v1|DV211088 3393 501 94.2 globlastp 1436 LNU45 orobanche|10v1|SRR023189S0002696 3394 501 94.2 globlastp 1437 LNU45 orobanche|10v1|SRR023189S0007530 3394 501 94.2 globlastp 1438 LNU45 solanum_phureja|09v1|SPHBG124194 3395 501 94.2 globlastp 1439 LNU45 apple|gb157.3|CO756008 3396 501 94.2 globlastp 1440 LNU45 arabidopsis|gb165|AT5G47930 3397 501 94.2 globlastp 1441 LNU45 banana|gb167|DN239263 3398 501 94.2 globlastp 1442 LNU45 canola|gb161|EE569888 3399 501 94.2 globlastp 1443 LNU45 catharanthus|gb166|EG560431 3400 501 94.2 globlastp 1444 LNU45 coffea|10v1|DV667447 3401 501 94.2 globlastp 1445 LNU45 coffea|gb157.2|DV667447 3401 501 94.2 globlastp 1446 LNU45 cotton|gb164|BF272631 3402 501 94.2 globlastp 1447 LNU45 dandelion|gb161|DY807943 3403 501 94.2 globlastp 1448 LNU45 ipomoea|gb157.2|CB330743 3391 501 94.2 globlastp 1449 LNU45 nicotiana_benthamiana|gb162| 3404 501 94.2 globlastp AY310774 1450 LNU45 nicotiana_benthamiana|gb162| 3405 501 94.2 globlastp CN743261 1451 LNU45 potato|gb157.2|AJ489106 3395 501 94.2 globlastp 1452 LNU45 potato|gb157.2|BM404024 3395 501 94.2 globlastp 1453 LNU45 radish|gb164|EY920230 3406 501 94.2 globlastp 1454 LNU45 rose|gb157.2|BQ106521 3407 501 94.2 globlastp 1455 LNU45 senecio|gb170|DY662196 3408 501 94.2 globlastp 1456 LNU45 sesame|10v1|BU670278 3409 501 94.2 globlastp 1457 LNU45 tobacco|gb162|CV016119 3404 501 94.2 globlastp 1458 LNU45 triphysaria|gb164|EY020166 3410 501 94.2 globlastp 1459 LNU45 pepper|gb171|BM066089 3411 501 94.19 glotblastn 1460 LNU45 pepper|gb157.2|BM062650 3412 501 94.19 glotblastn 1461 LNU45 avocado|10v1|FD507705 3413 501 93.02 glotblastn 1462 LNU45 barley|gb157SOLEXA|BE411675 3414 501 93.02 glotblastn 1462 LNU45 barley|gb157.3|BE411675 3417 501 93 globlastp 1463 LNU45 physcomitrella|gb157|AW127011 3415 501 93.02 glotblastn 1464 LNU45 eggplant|10v1|FS003716 3416 501 93 globlastp 1465 LNU45 oat|10v1|GO582478 3417 501 93 globlastp 1466 LNU45 orobanche|10v1|SRR023495S0023362 3418 501 93 globlastp 1467 LNU45 physcomitrella|10v1|AW126791 3419 501 93 globlastp 1468 LNU45 physcomitrella|10v1|AW126917 3419 501 93 globlastp 1469 LNU45 physcomitrella|10v1|AW127011 3419 501 93 globlastp 1470 LNU45 apple|gb157.3|EB115463 3420 501 93 globlastp 1471 LNU45 b_rapa|gb162|EX051142 3421 501 93 globlastp 1472 LNU45 banana|gb167|FL658637 3422 501 93 globlastp 1473 LNU45 barley|gb157SOLEXA|AL512188 3417 501 93 globlastp 1474 LNU45 barley|gb157SOLEXA|BE421731 3417 501 93 globlastp 1475 LNU45 brachypodium|09v1|DV471589 3417 501 93 globlastp 1476 LNU45 brachypodium|gb169|BE399584 3417 501 93 globlastp 1477 LNU45 brachypodium|09v1|DV471799 3423 501 93 globlastp 1478 LNU45 brachypodium|gb169|BE416572 3423 501 93 globlastp 1479 LNU45 cenchrus|gb166|BM084666 3424 501 93 globlastp 1480 LNU45 dandelion|gb161|DY809678 3425 501 93 globlastp 1481 LNU45 dandelion|gb161|DY838552 3425 501 93 globlastp 1482 LNU45 ginger|gb164|DY361313 3426 501 93 globlastp 1483 LNU45 lettuce|10v1|DW044248 3427 501 93 globlastp 1484 LNU45 lettuce|gb157.2|DW044248 3427 501 93 globlastp 1485 LNU45 lettuce|gb157.2|DW103448 3427 501 93 globlastp 1486 LNU45 lettuce|gb157.2|DW126058 3427 501 93 globlastp 1487 LNU45 lettuce|gb157.2|DW145140 3427 501 93 globlastp 1488 LNU45 leymus|gb166|CN465799 3417 501 93 globlastp 1489 LNU45 maize|gb170|LLDQ245642 3417 501 93 globlastp 1490 LNU45 oat|10v1|CN817047 3417 501 93 globlastp 1491 LNU45 oat|gb164|CN817047 3417 501 93 globlastp 1492 LNU45 petunia|gb171|CV299912 3428 501 93 globlastp 1493 LNU45 physcomitrella|gb157|AW126791 3419 501 93 globlastp 1494 LNU45 physcomitrella|gb157|AW126917 3419 501 93 globlastp 1495 LNU45 pine|gb157.2|AW754553 3429 501 93 globlastp 1496 LNU45 poppy|gb166|FE965482 3430 501 93 globlastp 1497 LNU45 pseudoroegnerial|gb167|FF351733 3417 501 93 globlastp 1498 LNU45 radish|gb164|FD579539 3431 501 93 globlastp 1499 LNU45 rye|gb164|BE494281 3417 501 93 globlastp 1500 LNU45 sugarcane|gb157.3|CA287147 3417 501 93 globlastp 1501 LNU45 tobacco|gb162|BQ842826 3418 501 93 globlastp 1502 LNU45 wheat|gb164|BE399584 3417 501 93 globlastp 1503 LNU45 wheat|gb164|BE443667 3417 501 93 globlastp 1504 LNU45 wheat|gb164|BF199537 3417 501 93 globlastp 1505 LNU45 wheat|gb164|BI751307 3417 501 93 globlastp 1506 LNU45 wheat|gb164|CA601804 3417 501 93 globlastp 1507 LNU45 lettuce|10v1|DW103448 3427 501 93 globlastp 1508 LNU45 orobanche|10v1|SRR023189S0090142 3432 501 92 globlastp 1509 LNU45 millet|09v1|EVO454PM260711 3433 501 91.9 globlastp 1510 LNU45 oat|10v1|GO586209 3434 501 91.9 globlastp 1511 LNU45 physcomitrella|10v1|AW155989 3435 501 91.9 globlastp 1512 LNU45 sorghum|09v1|SB01G008260 3433 501 91.9 globlastp 1513 LNU45 sugarcane|10v1|CA069593 3433 501 91.9 globlastp 1514 LNU45 arabidopsis|gb165|AT2G45710 3436 501 91.9 globlastp 1515 LNU45 fescue|gb161|DT686196 3437 501 91.9 globlastp 1516 LNU45 lovegrass|gb167|DN481942 3438 501 91.9 globlastp 1517 LNU45 lovegrass|gb167|EH188789 3439 501 91.9 globlastp 1518 LNU45 lovegrass|gb167|EH192368 3440 501 91.9 globlastp 1519 LNU45 maize|gb170|AI622704 3433 501 91.9 globlastp 1520 LNU45 maize|gb170|AI973383 3433 501 91.9 globlastp 1521 LNU45 maize|gb170|LLBI361219 3433 501 91.9 globlastp 1522 LNU45 maize|gb170|T23373 3433 501 91.9 globlastp 1523 LNU45 millet|09v1|EB410946 3441 501 91.9 globlastp 1524 LNU45 rice|gb170|OS02G27769 3442 501 91.9 globlastp 1525 LNU45 rosel|gb157.2|EC587400 3443 501 91.9 globlastp 1526 LNU45 sorghum|09v1|sb04g018990 3433 501 91.9 globlastp 1527 LNU45 switchgrass|gb167|FL610323 3433 501 91.9 globlastp 1528 LNU45 switchgrass|gb167|FL616250 3433 501 91.9 globlastp 1529 LNU45 switchgrass|gb167|FL631460 3433 501 91.9 globlastp 1530 LNU45 switchgrass|gb167|FL725078 3433 501 91.9 globlastp 1531 LNU45 switchgrass|gb167|FL741521 3433 501 91.9 globlastp 1532 LNU45 switchgrass|gb167|FL849448 3433 501 91.9 globlastp 1533 LNU45 switchgrass|gb167|FL940045 3433 501 91.9 globlastp 1534 LNU45 wheat|gb164|CA486248 3433 501 91.9 globlastp 1535 LNU45 sugarcane|10v1|BQ535468 3433 501 91.9 globlastp 1536 LNU45 sugarcane|10v1|BQ535613 3433 501 91.9 globlastp 1537 LNU45 orobanche|10v1|SRR023189S0004445 3444 501 90.7 globlastp 1538 LNU45 physcomitrella|10v1|BJ164117 3445 501 90.7 globlastp 1539 LNU45 amborella|gb166|FD430338 3446 501 90.7 globlastp 1540 LNU45 banana|gb167|DN239917 3447 501 90.7 glotblastn 1541 LNU45 cacao|gb167|CU493520 3448 501 90.7 globlastp 1542 LNU45 cenchrus|gb166|EB660456 3449 501 90.7 globlastp 1543 LNU45 dandelion|gb161|DY834568 3450 501 90.7 globlastp 1544 LNU45 kiwi|gb166|FG418840 3451 501 90.7 glotblastn 1545 LNU45 marchantia|gb166|C95731 3452 501 90.7 globlastp 1546 LNU45 rice|gb170|OS04G27860 3453 501 90.7 globlastp 1547 LNU45 maize|gb170|LLFL411499 3454 501 89.53 glotblastn 1548 LNU45 switchgrass|gb167|FE624276 3455 501 89.53 glotblastn 1549 LNU45 rice|gb170|OS04G32710 3456 501 89.5 globlastp 1550 LNU45 spikemoss|gb165|DN838335 3457 501 89.5 globlastp 1551 LNU45 spikemoss|gb165|DN839110 3457 501 89.5 globlastp 1552 LNU45 fern|gb171|BP913163 3458 501 88.4 globlastp 1553 LNU45 ginseng|10v1|CN845877 3459 501 88.4 globlastp 1554 LNU45 ginseng|10v1|GR875257 3459 501 88.4 globlastp 1555 LNU45 rye|gb164|BE705802 3460 501 88.4 globlastp 1556 LNU45 canola|10v1|CD812394 3461 501 88.3 globlastp 1557 LNU45 fern|gb171|DK944513 3462 501 87.2 globlastp 1558 LNU45 b_juncea|gb164|EVGN00943108632248 3463 501 87.2 globlastp 1559 LNU45 chlamydomonas|gb162|X83694 3464 501 87.2 globlastp 1560 LNU45 volvox|gb162|X83694 3465 501 87.2 globlastp 1561 LNU45 citrus|gb166|CX663339 3466 501 86 globlastp 1562 LNU45 lovegrass|gb167|EH190160 3467 501 86 globlastp 1563 LNU45 mesostigma|gb166|DN254596 3468 501 86 globlastp 1564 LNU45 mesostigma|gb166|EC728430 3468 501 86 globlastp 1565 LNU45 arabidopsis_lyrata|09v1|JGIAL019416 3469 501 84.9 globlastp 1566 LNU45 heritiera|10v1|SRR005794S0004655 3470 501 84.9 globlastp 1567 LNU45 arabidopsis|gb165|AT3G61111 3471 501 82.6 globlastp 1568 LNU45 rye|gb164|BF146222 3472 501 82.6 globlastp 1569 LNU45 wheat|gb164|CA606076 3473 501 81.7 globlastp 1570 LNU45 solanum_phureja|09v1|SPHCRPSP011443 3474 501 81.4 glotblastn 1571 LNU45 citrus|gb166|DY261826 3475 501 81.4 globlastp 1572 LNU45 ostreococcus|gb162|XM001421510 3476 501 81.4 glotblastn 1573 LNU45 spruce|gb162|ES252989 3477 501 81.4 globlastp 1574 LNU45 switchgrass|gb167|GD026676 3478 501 81.4 glotblastn 1575 LNU45 coffea|10v1|GR981069 — 501 81.4 glotblastn 1576 LNU46 soybean|gb168|AW428695 3479 502 97.5 globlastp 1577 LNU46 cowpea|gb166|FF399962 3480 502 97 globlastp 1578 LNU46 lotus|09v1|AW428695 3481 502 96.1 globlastp 1579 LNU46 bean|gb167|CA898025 3482 502 96.1 globlastp 1580 LNU46 citrus|gb166|CF418615 3483 502 95.7 globlastp 1581 LNU46 cotton|gb164|CO109391 3484 502 95.7 globlastp 1582 LNU46 grape|gb160|BQ795999 3485 502 95.7 globlastp 1583 LNU46 cucumber|09v1|BGI454G0029699 3486 502 95.4 globlastp 1584 LNU46 cowpea|gb166|FF400935 3487 502 95.4 globlastp 1585 LNU46 poplar|10v1|BI120740 3488 502 95.4 globlastp 1586 LNU46 poplar|gb170|BI120740 3488 502 95.4 globlastp 1587 LNU46 cucumber|09v1|CV001012 3489 502 95.2 globlastp 1588 LNU46 castorbean|09v1|T15123 3490 502 95 globlastp 1589 LNU46 castorbean|gb160|T15123 3490 502 95 globlastp 1590 LNU46 kiwi|gb166|FG426103 3491 502 95 globlastp 1591 LNU46 cassava|09v1|DB921974 3492 502 94.7 globlastp 1592 LNU46 cycas|gb166|CB089800 3493 502 94.7 globlastp 1593 LNU46 medicago|09v1|AL376549 3494 502 94.7 globlastp 1594 LNU46 medicago|gb157.2|AL376549 3494 502 94.7 globlastp 1595 LNU46 spruce|gb162|CO226322 3495 502 94.7 globlastp 1596 LNU46 millet|09v1|EVO454PM007367 3496 502 94.5 globlastp 1597 LNU46 artemisia|gb164|EY071317 3497 502 94.5 globlastp 1598 LNU46 cacao|gb167|CU477411 3498 502 94.5 globlastp 1599 LNU46 aquilegia|10v1|DR925421 3499 502 94.3 globlastp 1600 LNU46 aquilegia|gb157.3|DR925421 3499 502 94.3 globlastp 1601 LNU46 maize|gb170|AI932193 3500 502 94.3 globlastp 1602 LNU46 sorghum|09v1|SB01G010860 3501 502 94.3 globlastp 1603 LNU46 sorghum|gb161.crp|BG051224 3501 502 94.3 globlastp 1604 LNU46 poplar|10v1|XM002304585 3502 502 94.1 globlastp 1605 LNU46 cynara|gb167|GE577142 3503 502 94.1 globlastp 1606 LNU46 lettuce|10v1|DW046496 3504 502 94.1 globlastp 1607 LNU46 lettuce|gb157.2|DW124917 3504 502 94.1 globlastp 1608 LNU46 oil_palm|gb166|ES273702 3505 502 94.1 globlastp 1609 LNU46 poplar|10v1|BI068703 3502 502 94.1 globlastp 1610 LNU46 poplar|gb170|BI068703 3502 502 94.1 globlastp 1611 LNU46 tomato|09v1|AI486841 3506 502 94.1 globlastp 1612 LNU46 tomato|gb164|AI486841 3506 502 94.1 globlastp 1613 LNU46 solanum_phureja|09v1|SPHAI486841 3507 502 93.8 globlastp 1614 LNU46 poplar|10v1|BI129155 3508 502 93.8 globlastp 1615 LNU46 poplar|gb170|BI129155 3508 502 93.8 globlastp 1616 LNU46 rice|gb170|OS03G49580 3509 502 93.8 globlastp 1617 LNU46 switchgrass|gb167|FE599427 3510 502 93.8 globlastp 1618 LNU46 switchgrass|gb167|FE604633 3511 502 93.8 globlastp 1619 LNU46 centaurea|gb166|EL934628 3512 502 93.6 globlastp 1620 LNU46 rice|gb170|OS07G39870 3513 502 93.6 globlastp 1621 LNU46 sugarcane|10v1|CA089292 3514 502 93.6 globlastp 1622 LNU46 sugarcane|gb157.3|CA089292 3514 502 93.6 globlastp 1623 LNU46 monkeyflower|10v1|GO963384 3515 502 93.4 globlastp 1624 LNU46 apple|gb157.3|CN493322 3516 502 93.4 globlastp 1625 LNU46 apple|gb171|CN493322 3516 502 93.4 globlastp 1626 LNU46 maize|gb170|BG354242 3517 502 93.4 globlastp 1627 LNU46 sorghum|09v1|SB02G037930 3518 502 93.4 globlastp 1628 LNU46 sorghum|gb161.crp|AW671733 3518 502 93.4 globlastp 1629 LNU46 strawberry|gb164|DY666824 3519 502 93.4 globlastp 1630 LNU46 chestnut|gb170|SRR006295S0030165 3520 502 93.1 globlastp 1631 LNU46 cotton|gb164|BG439937 3521 502 93.1 globlastp 1632 LNU46 oak|gb170|DB998392 3522 502 93.1 globlastp 1633 LNU46 arabidopsis|gb165|AT3G26618 3523 502 92.9 globlastp 1634 LNU46 cotton|gb164|AI054657 3524 502 92.9 globlastp 1635 LNU46 pine|10v1|AI812442 3525 502 92.7 globlastp 1636 LNU46 pine|gb157.2|AI812442 3525 502 92.7 globlastp 1637 LNU46 prunus|gb167|BU039215 3526 502 92.7 globlastp 1638 LNU46 soybean|gb168|AW691393 3527 502 92.7 globlastp 1639 LNU46 pepper|gb171|BM063924 3528 502 92.4 globlastp 1640 LNU46 citrus|gb166|CB291077 3529 502 92.4 globlastp 1641 LNU46 sunflower|gb162|CD845824 3530 502 92.4 globlastp 1642 LNU46 tomato|09v1|BG129404 3531 502 92.4 globlastp 1643 LNU46 tomato|gb164|BG129404 3531 502 92.4 globlastp 1644 LNU46 arabidopsis_lyrata|09v1|JGIAL016770 3532 502 92.2 globlastp 1645 LNU46 apple|gb157.3|CN544908 3533 502 92.2 globlastp 1646 LNU46 apple|gb171|CN544908 3533 502 92.2 globlastp 1647 LNU46 barley|gb157SOLEXA|BE421791 3534 502 92.2 globlastp 1648 LNU46 cowpea|gb166|FF399895 3535 502 92.2 globlastp 1649 LNU46 oat|10v1|CN820661 3536 502 92 globlastp 1650 LNU46 solanum_phureja|09v1|SPHBG129404 3537 502 92 globlastp 1651 LNU46 potato|10v1|BF053654 3537 502 92 globlastp 1652 LNU46 potato|gb157.2|BF053654 3537 502 92 globlastp 1653 LNU46 soybean|gb168|AW428757 3538 502 91.8 globlastp 1654 LNU46 spruce|gb162|CO220375 3539 502 91.8 globlastp 1655 LNU46 triphysaria|gb164|EX991156 3540 502 91.8 globlastp 1656 LNU46 physcomitrella|10v1|BJ175132 3541 502 91.6 globlastp 1657 LNU46 physcomitrella|gb157|BJ175017 3541 502 91.6 globlastp 1658 LNU46 canola|10v1|CD824781 3542 502 91.5 globlastp 1659 LNU46 oat|10v1|BE439128 3543 502 91.5 globlastp 1660 LNU46 brachypodium|09v1|DV471205 3544 502 91.5 globlastp 1661 LNU46 brachypodium|gb169|BE446313 3544 502 91.5 globlastp 1662 LNU46 papaya|gb165|AM904175 3545 502 91.5 globlastp 1663 LNU46 sunflower|gb162|DY910709 3546 502 91.5 globlastp 1664 LNU46 barley|gb157SOLEXA|BE438955 3547 502 91.3 globlastp 1665 LNU46 canola|gb161|DY011567 3548 502 91.3 globlastp 1666 LNU46 fescue|gb161|DT700877 3549 502 91.3 globlastp 1667 LNU46 wheat|gb164|BU099476 3550 502 91.3 globlastp 1668 LNU46 physcomitrella|10v1|BY984317 3551 502 91.2 globlastp 1669 LNU46 physcomitrella|10v1|BQ827517 3552 502 90.9 globlastp 1670 LNU46 physcomitrella|gb157|BQ827517 3553 502 90.87 glotblastn 1671 LNU46 coffea|10v1|DV667361 3554 502 90.8 globlastp 1672 LNU46 potato|10v1|BF154263 3555 502 90.8 globlastp 1673 LNU46 potato|gb157.2|BF154263 3555 502 90.8 globlastp 1674 LNU46 dandelion|gb161|DY809008 3556 502 90.7 globlastp 1675 LNU46 canola|10v1|EE407094 3557 502 90.6 globlastp 1676 LNU46 pepper|gb171|CA523256 3558 502 90.6 globlastp 1677 LNU46 solanum_phureja|09v1|SPHAA824687 3559 502 90.6 globlastp 1678 LNU46 solanum_phureja|09v1|SPHAJ489160 3560 502 90.6 globlastp 1679 LNU46 canola|10v1|CD815302 3557 502 90.6 globlastp 1680 LNU46 canola|gb161|CD815302 3557 502 90.6 globlastp 1681 LNU46 medicago|09v1|AW691393 3561 502 90.6 globlastp 1682 LNU46 medicago|gb157.2|AW691393 3561 502 90.6 globlastp 1683 LNU46 pine|10v1|AW010603 3562 502 90.6 globlastp 1684 LNU46 tomato|09v1|AA824687 3563 502 90.6 globlastp 1685 LNU46 tomato|09v1|AJ489160 3564 502 90.4 globlastp 1686 LNU46 pine|gb157.2|AW010603 3565 502 90.4 globlastp 1687 LNU46 tomato|gb164|AA824687 3566 502 90.4 globlastp 1688 LNU46 potato|10v1|AJ489160 3567 502 90.39 glotblastn 1689 LNU46 arabidopsis_lyrata|09v1|JGIAL001354 3568 502 90.2 globlastp 1690 LNU46 monkeyflower|10v1|DV209146 3569 502 89.9 globlastp 1691 LNU46 arabidopsis|gb165|AT1G12910 3570 502 89.9 globlastp 1692 LNU46 coffea|gb157.2|DV667361 3571 502 89.9 globlastp 1693 LNU46 tobacco|gb162|CV016199 3572 502 89.5 globlastp 1694 LNU46 radish|gb164|EV534949 3573 502 89.47 glotblastn 1695 LNU46 physcomitrella|10v1|BJ175017 3574 502 89.4 globlastp 1696 LNU46 spikemoss|gb165|FE441264 3575 502 88.1 globlastp 1697 LNU46 arabidopsis_lyrata|09v1|JGIAL028997 3576 502 87.9 globlastp 1698 LNU46 arabidopsis|gb165|AT5G47880 3577 502 87.9 globlastp 1699 LNU46 spikemoss|gb165|FE441265 3578 502 87.6 globlastp 1700 LNU46 radish|gb164|EV569528 3579 502 87.5 globlastp 1701 LNU46 canola|10v1|CD814349 3580 502 87 globlastp 1702 LNU46 rice|gb170|OS01G71270 3581 502 87 globlastp 1703 LNU46 brachypodium|09v1|DV469404 3582 502 86.3 globlastp 1704 LNU46 brachypodium|gb169|BG606860 3582 502 86.3 globlastp 1705 LNU46 soybean|gb168|AL376550 3583 502 86.04 glotblastn 1706 LNU46 medicago|09v1|CRPMT036602 3584 502 83.5 globlastp 1707 LNU46 millet|09v1|CD724536 3585 502 83.1 globlastp 1708 LNU46 papaya|gb165|EX253193 3586 502 81.7 globlastp 1709 LNU46 switchgrass|gb167|FE602227 3587 502 80.9 globlastp 1710 LNU46 onion|gb162|CF441127 3588 502 80.55 glotblastn 1711 LNU46 sorghum|09v1|SB09G018630 3589 502 80.2 globlastp 1712 LNU46 sorghum|gb161.crp|BE362758 3589 502 80.2 globlastp 1713 LNU48 switchgrass|gb167|FE638123 3590 503 89 globlastp 1714 LNU48 brachypodium|09v1|DV472885 3591 503 88.37 glotblastn 1715 LNU48 sorghum|09v1|SB02G032700 3592 503 87.2 globlastp 1716 LNU48 sorghum|gb161.crp|AW256150 3593 503 86.82 glotblastn 1717 LNU48 maize|gb170|AW256150 3594 503 86.6 globlastp 1718 LNU51 sorghum|09v1|SB02G028140 3595 505 82.6 globlastp 1719 LNU51 sorghum|gb161.crp|AW520040 3595 505 82.6 globlastp 1720 LNU51 maize|gb170|AW060000 3596 505 82.2 globlastp 1721 LNU51 sugarcane|gb157.3|CA070485 3597 505 81.57 glotblastn 1722 LNU51 brachypodium|09v1|GT760634 3598 505 81.5 globlastp 1723 LNU51 barley|gb157.3|AL499810 3599 505 81.3 globlastp 1724 LNU51 barley|gb157SOLEXA|AL499810 3599 505 81.3 globlastp 1725 LNU51 sugarcane|10v1|CA070485 3600 505 81 globlastp 1726 LNU52 sugarcane|gb157.3|CA075246 3601 506 92.6 globlastp 1727 LNU52 sorghum|09v1|SB01G047930 3602 506 92.4 globlastp 1728 LNU52 sorghum|gb161.crp|AW433438 3602 506 92.4 globlastp 1729 LNU52 brachypodium|gb169|BE400443 3603 506 92.01 glotblastn 1730 LNU52 brachypodium|09v1|DV470543 3604 506 91.8 globlastp 1731 LNU52 maize|gb170|BE123353 3605 506 91.6 globlastp 1732 LNU52 switchgrass|gb167|DN141859 3606 506 91 globlastp 1733 LNU52 switchgrass|gb167|DN147113 3607 506 90.5 globlastp 1734 LNU52 maize|gb170|AW076488 3608 506 89.5 globlastp 1735 LNU52 wheat|gb164|BE400443 3609 506 89 globlastp 1736 LNU52 oat|10v1|GR316421 3610 506 88 globlastp 1737 LNU52 brachypodium|gb169|BE399305 3611 506 87.2 globlastp 1738 LNU52 barley|gb157SOLEXA|BF623122 3612 506 87.1 globlastp 1739 LNU52 wheat|gb164|BE399305 3613 506 87.1 globlastp 1740 LNU52 barley|gb157SOLEXA|AL505656 3614 506 86.5 globlastp 1741 LNU52 brachypodium|09v1|GT766862 3615 506 85.5 globlastp 1742 LNU56 bean|gb167|CA909969 3616 510 88.8 globlastp 1743 LNU56 cowpea|gb166|FC458698 3617 510 88.78 glotblastn 1744 LNU56 medicago|09v1|LLEX523937 3618 510 85.6 globlastp 1745 LNU56 chickpea|09v2|GR401628 3619 510 83.6 globlastp 1746 LNU56 peanut|gb171|ES762633 3620 510 83 globlastp 1747 LNU56 medicago|09v1|AL374335 3621 510 82.1 globlastp 1748 LNU56 medicago|gb157.2|AL374335 3621 510 82.1 globlastp 1749 LNU56 prunus|gb167|BU043945 3622 510 81 globlastp 1750 LNU56 chestnut|gb170|SRR006295S0008375 3623 510 80.5 globlastp 1751 LNU56 poplar|gb170|BU876352 3624 510 80.5 globlastp 1752 LNU56 cucumber|09v1|AM717347 3625 510 80 globlastp 1753 LNU56 poplar|10v1|BU876352 3626 510 80 globlastp 1754 LNU57 wheat|gb164|BE431144 3627 511 86.8 globlastp 1755 LNU57 pseudoroegneria|gb167|FF351563 3628 511 85.4 globlastp 1755 LNU81 pseudoroegneria|gb167|FF351563 3628 728 85.9 globlastp 1756 LNU60 brachypodium|09v1|SRR031797S0000144 3629 514 88.2 globlastp 1756 LNU84 brachypodium|09v1|SRR031797S0000144 3629 533 80.8 globlastp 1756 LNU65 brachypodium|09v1|SRR031797S0000144 3629 722 80.5 globlastp 1757 LNU60 maize|gb170|AW562715 3630 514 80.6 globlastp 1757 LNU84 maize|gb170|AW562715 3630 533 90.9 globlastp 1758 LNU61 brachypodium|09v1|DV488685 3631 515 86.8 globlastp 1759 LNU63 pseudoroegneria|gb167|FF366744 3632 516 93.8 globlastp 1760 LNU63 wheat|gb164|CD937806 3633 516 90.1 globlastp 1761 LNU63 wheat|gb164|BF485055 3634 516 89.3 globlastp 1762 LNU63 barley|gb157.3|AL508288 3635 516 82.3 globlastp 1763 LNU63 barley|gb157SOLEXA|AL508288 3635 516 82.3 globlastp 1764 LNU63 leymus|gb166|EG402462 3636 516 81.8 globlastp 1765 LNU64 wheat|gb164|BG907753 3637 517 97.1 globlastp 1766 LNU64 wheat|gb164|BQ842100 3638 517 93.1 globlastp 1766 LNU98 wheat|gb164|BQ842100 3638 734 80.57 glotblastn 1767 LNU64 brachypodium|09v1|GT761032 3639 517 88.25 glotblastn 1768 LNU64 switchgrass|gb167|FE631036 3640 517 85.8 globlastp 1768 LNU98 switchgrass|gb167|FE631036 3640 734 84.2 globlastp 1769 LNU64 maize|gb170|AW438149 3641 517 84.3 globlastp 1769 LNU98 maize|gb170|AW438149 3641 734 81.1 globlastp 1770 LNU64 rice|gb170|OS06G05700 3642 517 83.9 globlastp 1770 LNU98 rice|gb170|OS06G05700 3642 734 81.1 globlastp 1771 LNU64 brachypodium|gb169|BE591591 3643 517 80.46 glotblastn 1772 LNU67 brachypodium|09v1|GT769610 3644 519 88.4 globlastp 1773 LNU67 barley|gb157.3|AL510475 3645 519 86.13 glotblastn 1774 LNU67 barley|gb157SOLEXA|AL510475 3645 519 86.13 glotblastn 1775 LNU67 sorghum|09v1|SB01G029600 3646 519 85.4 globlastp 1776 LNU67 sugarcane|10v1|CA073684 3647 519 85.4 globlastp 1777 LNU67 sugarcane|gb157.3|CA073684 3648 519 85.4 globlastp 1778 LNU67 sorghum|gb161.crp|AI586547 3646 519 85.4 globlastp 1779 LNU67 maize|gb170|AI586547 3649 519 84.2 globlastp 1780 LNU67 brachypodium|gb169|BG418808 3650 519 81.3 globlastp 1781 LNU67 switchgrass|gb167|FE612667 3651 519 80.3 globlastp 1782 LNU69 brachypodium|09v1|DV472747 3652 521 87.1 globlastp 1783 LNU69 oat|10v1|GR321530 3653 521 86.36 glotblastn 1784 LNU69 oat|10v1|GO589136 3654 521 85.9 globlastp 1785 LNU69 wheat|gb164|BE637681 3655 521 85.5 globlastp 1786 LNU69 barley|gb157SOLEXA|BI950025 3656 521 84.5 globlastp 1787 LNU69 barley|gb157.3|BI950025 3657 521 84.2 globlastp 1788 LNU69 pseudoroegneria|gb167|FF340678 3658 521 84.2 globlastp 1789 LNU69 brachypodium|gb169|BE637681 3659 521 81.6 globlastp 1790 LNU69 sorghum|gb161.crp|BG049299 3660 521 81.2 globlastp 1791 LNU69 maize|gb170|AI861497 3661 521 81.2 globlastp 1792 LNU69 sorghum|09v1|SB07G026190 3660 521 81.2 globlastp 1793 LNU69 sugarcane|10v1|CA090545 3662 521 81.2 globlastp 1794 LNU69 sugarcane|gb157.3|CA090545 3663 521 80.8 globlastp 1795 LNU71 rice|gb170|OS01G72240 3664 523 83 globlastp 1796 LNU71 oat|10v1|GR359520 3665 523 82.39 glotblastn 1797 LNU71 sorghum|09v1|SB03G045930 3666 523 82.1 globlastp 1798 LNU71 sorghum|gb161.crp|AI396343 3666 523 82.1 globlastp 1799 LNU71 sorghum|09v1|SB03G045940 3667 523 81.4 globlastp 1800 LNU71 maize|gb170|AI396343 3668 523 81.1 globlastp 1801 LNU71 maize|gb170|AI668476 3669 523 80.6 globlastp 1802 LNU73 sorghum|09v1|SB01G031850 3670 525 83.6 globlastp 1803 LNU73 sorghum|gb161.crp|AI665094 3670 525 83.6 globlastp 1804 LNU73 brachypodium|09v1|DV478838 3671 525 81.2 globlastp 1805 LNU73 brachypodium|gb169|BE585945 3672 525 80.9 globlastp 1806 LNU73 oat|10v1|GR315201 3673 525 80.8 globlastp 1807 LNU73 leymus|gb166|EG395112 3674 525 80.6 globlastp 1808 LNU73 wheat|gb164|BE213619 3675 525 80.6 globlastp 1809 LNU73 maize|gb170|AI600420 3676 525 80.2 globlastp 1810 LNU73 barley|gb157SOLEXA|AL507770 3677 525 80 globlastp 1811 LNU74 poplar|gb170|AI164221 3678 526 94.8 globlastp 1812 LNU74 poplar|10v1|AI164221 3679 526 94 globlastp 1813 LNU74 cassava|09v1|DV441703 3680 526 93.3 globlastp 1814 LNU74 castorbean|09v1|EE256800 3681 526 93.3 globlastp 1815 LNU74 cassava|09v1|BM260313 3682 526 92.5 globlastp 1816 LNU74 cassava|gb164|BM260313 3682 526 92.5 globlastp 1817 LNU74 cassava|gb164|DV441703 3683 526 92.5 globlastp 1818 LNU74 castorbean|gb160|EE256800 3684 526 92.5 globlastp 1819 LNU74 banana|gb167|ES432444 3685 526 91.8 globlastp 1820 LNU74 citrus|gb166|BQ624628 3686 526 91.8 globlastp 1821 LNU74 papaya|gb165|EX290028 3687 526 91.8 globlastp 1822 LNU74 banana|gb167|FL665867 3688 526 91 globlastp 1823 LNU74 papaya|gb165|AM903637 3689 526 91 globlastp 1824 LNU74 poplar|10v1|BU817024 3690 526 91 globlastp 1825 LNU74 poplar|gb170|BU817024 3690 526 91 globlastp 1826 LNU74 kiwi|gb166|FG488574 3691 526 90.4 globlastp 1827 LNU74 citrus|gb166|BQ624990 3692 526 90.3 globlastp 1828 LNU74 poplar|10v1|BU813474 3693 526 90.3 globlastp 1829 LNU74 poplar|gb170|BU813474 3693 526 90.3 globlastp 1830 LNU74 bruguiera|gb166|BP946426 3694 526 89.6 globlastp 1831 LNU74 sesame|gb157.2|BU668642 3695 526 89.6 globlastp 1832 LNU74 sesame|10v1|BU667940 3696 526 88.81 glotblastn 1833 LNU74 jatropha|09v1|FM893408 3697 526 88.8 globlastp 1834 LNU74 cacao|gb167|CU491187 3698 526 88.8 globlastp 1835 LNU74 castorbean|09v1|XM002529794 3699 526 88.8 globlastp 1836 LNU74 ginger|gb164|DY377849 3700 526 88.8 globlastp 1837 LNU74 grape|gb160|BQ797018 3701 526 88.8 globlastp 1838 LNU74 spurge|gb161|BE095323 3702 526 88.8 globlastp 1839 LNU74 cleome_gynandra|10v1|SRR015532S0006733 3703 526 88.1 globlastp 1840 LNU74 heritiera|10v1|SRR005795S0013040 3704 526 88.1 globlastp 1841 LNU74 aquilegia|10v1|DR915465 3705 526 88.1 globlastp 1842 LNU74 basilicum|10v1|DY341993 3706 526 88.1 globlastp 1843 LNU74 castorbean|gb160|MDL28492M000475 3707 526 88.1 globlastp 1844 LNU74 grape|gb160|CB004623 3708 526 88.1 globlastp 1845 LNU74 centaurea|gb166|EH742056 3709 526 87.9 globlastp 1846 LNU74 apple|gb171|CN581387 3710 526 87.3 globlastp 1847 LNU74 solanum_phureja|09v1|SPHBG123695 3711 526 87.3 globlastp 1848 LNU74 apple|gb157.3|CN444719 3712 526 87.3 globlastp 1849 LNU74 apple|gb171|CN444719 3712 526 87.3 globlastp 1850 LNU74 ginger|gb164|DY357017 3713 526 87.3 globlastp 1851 LNU74 potato|gb157.2|BF153790 3711 526 87.3 globlastp 1852 LNU74 potato|gb157.2|BG591609 3711 526 87.3 globlastp 1853 LNU74 spurge|gb161|BI993550 3714 526 87.3 globlastp 1854 LNU74 spurge|gb161|DV120560 3715 526 87.3 globlastp 1855 LNU74 thellungiella|gb167|DN772768 3716 526 87.3 globlastp 1856 LNU74 triphysaria|gb164|EX991312 3717 526 87.3 globlastp 1857 LNU74 triphysaria|gb164|EX992098 3718 526 87.3 globlastp 1858 LNU74 triphysaria|gb164|EX993270 3719 526 87.3 globlastp 1859 LNU74 potato|10v1|BF153790 3711 526 87.3 globlastp 1860 LNU74 canola|10v1|BQ704346 3720 526 86.6 globlastp 1861 LNU74 canola|10v1|CD812655 3720 526 86.6 globlastp 1862 LNU74 canola|10v1|CD817750 3720 526 86.6 globlastp 1863 LNU74 canola|10v1|CD820979 3720 526 86.6 globlastp 1864 LNU74 canola|10v1|CD822847 3720 526 86.6 globlastp 1865 LNU74 canola|10v1|CD839803 3720 526 86.6 globlastp 1866 LNU74 canola|10v1|CD840413 3720 526 86.6 globlastp 1867 LNU74 cleome_gynandra|10v1|SRR015532S0001567 3721 526 86.6 globlastp 1868 LNU74 liquorice|gb171|FS239300 3722 526 86.6 globlastp 1869 LNU74 monkeyflower|10v1|DV211742 3723 526 86.6 globlastp 1870 LNU74 orobanche|10v1|SRR023189S0022715 3724 526 86.6 globlastp 1871 LNU74 rhizophora|10v1|SRR005792S0001265 3725 526 86.6 globlastp 1872 LNU74 salvia|10v1|CV170183 3726 526 86.6 globlastp 1873 LNU74 b_juncea|gb164|EVGN00065811011380 3720 526 86.6 globlastp 1874 LNU74 b_juncea|gb164|EVGN00096612141341 3720 526 86.6 globlastp 1875 LNU74 b_juncea|gb164|EVGN00247926600394 3720 526 86.6 globlastp 1876 LNU74 b_juncea|gb164|EVGN00581615062911 3720 526 86.6 globlastp 1877 LNU74 b_juncea|gb164|EVGN01024809191906 3720 526 86.6 globlastp 1878 LNU74 b_oleracea|gb161|DY025798 3720 526 86.6 globlastp 1879 LNU74 b_oleracea|gb161|DY026115 3727 526 86.6 globlastp 1880 LNU74 b_rapa|gb162|CA992036 3720 526 86.6 globlastp 1881 LNU74 b_rapa|gb162|CX265596 3720 526 86.6 globlastp 1882 LNU74 b_rapa|gb162|CX265986 3720 526 86.6 globlastp 1883 LNU74 b_rapa|gb162|DY013411 3720 526 86.6 globlastp 1884 LNU74 b_rapa|gb162|L35798 3720 526 86.6 globlastp 1885 LNU74 cacao|gb167|CU473549 3728 526 86.6 globlastp 1886 LNU74 canola|gb161|CD812655 3720 526 86.6 globlastp 1887 LNU74 canola|gb161|CD817750 3720 526 86.6 globlastp 1888 LNU74 canola|gb161|CD818582 3720 526 86.6 globlastp 1889 LNU74 canola|gb161|CD820979 3720 526 86.6 globlastp 1890 LNU74 canola|gb161|CD822847 3720 526 86.6 globlastp 1891 LNU74 canola|gb161|CD839803 3720 526 86.6 globlastp 1892 LNU74 canola|gb161|CN731800 3720 526 86.6 globlastp 1893 LNU74 cotton|gb164|AI726252 3729 526 86.6 globlastp 1894 LNU74 cotton|gb164|BE054575 3730 526 86.6 globlastp 1895 LNU74 cotton|gb164|BF268166 3731 526 86.6 globlastp 1896 LNU74 ginger|gb164|DY347722 3732 526 86.6 globlastp 1897 LNU74 kiwi|gb166|FG426073 3733 526 86.6 globlastp 1898 LNU74 maize|gb170|LLDQ244555 3720 526 86.6 globlastp 1899 LNU74 oil_palm|gb166|EL684957 3734 526 86.6 globlastp 1900 LNU74 pepper|gb171|CA521239 3735 526 86.6 globlastp 1901 LNU74 radish|gb164|EV524672 3720 526 86.6 globlastp 1902 LNU74 radish|gb164|EV535208 3720 526 86.6 globlastp 1903 LNU74 radish|gb164|EV536989 3720 526 86.6 globlastp 1904 LNU74 radish|gb164|EV538098 3720 526 86.6 globlastp 1905 LNU74 radish|gb164|EV544188 3720 526 86.6 globlastp 1906 LNU74 radish|gb164|EX751329 3720 526 86.6 globlastp 1907 LNU74 radish|gb164|EX904913 3720 526 86.6 globlastp 1908 LNU74 radish|gb164|T25169 3720 526 86.6 globlastp 1909 LNU74 tamarix|gb166|CV791366 3736 526 86.6 globlastp 1910 LNU74 tomato|09v1|BG128242 3737 526 86.6 globlastp 1911 LNU74 tomato|gb164|BG128242 3737 526 86.6 globlastp 1912 LNU74 triphysaria|gb164|CB815081 3738 526 86.6 globlastp 1913 LNU74 sesame|gb157.2|BU667940 3739 526 86.57 glotblastn 1914 LNU74 cotton|gb164|BE052419 3740 526 86 globlastp 1915 LNU74 cleome_gynandra|10v1|SRR015532S0035591 3741 526 85.8 globlastp 1916 LNU74 eggplant|10v1|FS014035 3742 526 85.8 globlastp 1917 LNU74 monkeyflower|10v1|DV208750 3743 526 85.8 globlastp 1918 LNU74 orobanche|10v1|SRR023189S0004356 3744 526 85.8 globlastp 1919 LNU74 potato|10v1|BG589981 3745 526 85.8 globlastp 1920 LNU74 rhizophora|10v1|SRR005793S0025926 3746 526 85.8 globlastp 1921 LNU74 solanum_phureja|09v1|SPHBG128242 3745 526 85.8 globlastp 1922 LNU74 solanum_phureja|09v1|SPHBG131313 3747 526 85.8 globlastp 1923 LNU74 antirrhinum|gb166|AJ558344 3748 526 85.8 globlastp 1924 LNU74 avocado|10v1|CV461343 3749 526 85.8 globlastp 1925 LNU74 banana|gb167|DN239293 3750 526 85.8 globlastp 1926 LNU74 basilicum|gb157.3|DY341993 3751 526 85.8 globlastp 1927 LNU74 catharanthus|gb166|EG554531 3752 526 85.8 globlastp 1928 LNU74 chestnut|gb170|SRR006295S0004660 3753 526 85.8 globlastp 1929 LNU74 chestnut|gb170|SRR006295S0005476 3754 526 85.8 globlastp 1930 LNU74 kiwi|gb166|FG412937 3755 526 85.8 globlastp 1931 LNU74 kiwi|gb166|FG418868 3756 526 85.8 globlastp 1932 LNU74 oak|gb170|DB996491 3754 526 85.8 globlastp 1933 LNU74 oak|gb170|DN950062 3753 526 85.8 globlastp 1934 LNU74 oil_palm|gb166|CN600372 3757 526 85.8 globlastp 1935 LNU74 pineapple|10v1|DT336533 3758 526 85.8 globlastp 1936 LNU74 potato|10v1|BG350007 3747 526 85.8 globlastp 1937 LNU74 potato|gb157.2|BG350007 3747 526 85.8 globlastp 1938 LNU74 potato|gb157.2|BG589981 3745 526 85.8 globlastp 1939 LNU74 prunus|gb167|CB819261 3759 526 85.8 globlastp 1940 LNU74 prunus|gb167|CB819309 3760 526 85.8 globlastp 1941 LNU74 radish|gb164|EV543656 3761 526 85.8 globlastp 1942 LNU74 strawberry|gb164|DY674514 3762 526 85.8 globlastp 1943 LNU74 tomato|09v1|BG123695 3763 526 85.8 globlastp 1944 LNU74 tomato|gb164|BG123695 3763 526 85.8 globlastp 1945 LNU74 tomato|09v1|BG131313 3764 526 85.8 globlastp 1946 LNU74 tomato|gb164|BG131313 3764 526 85.8 globlastp 1947 LNU74 cleome_spinosa|10v1|SRR015531S0000037 3765 526 85.1 globlastp 1948 LNU74 cleome_spinosa|10v1|SRR015531S0001284 3766 526 85.1 globlastp 1949 LNU74 cleome_spinosa|10v1|SRR015531S0008654 3767 526 85.1 globlastp 1950 LNU74 eggplant|10v1|FS000830 3768 526 85.1 globlastp 1951 LNU74 ginseng|10v1|CN846360 3769 526 85.1 globlastp 1952 LNU74 ipomoea_batatas|10v1|BU691765 3770 526 85.1 globlastp 1953 LNU74 ipomoea_nil|10v1|BJ560886 3771 526 85.1 globlastp 1954 LNU74 salvia|10v1|CV169031 3772 526 85.1 globlastp 1955 LNU74 apple|gb157.3|CN443979 3773 526 85.1 globlastp 1956 LNU74 apple|gb171|CN443979 3773 526 85.1 globlastp 1957 LNU74 apple|gb171|CN579105 3774 526 85.1 globlastp 1958 LNU74 arabidopsis|gb165|AT2G20450 3775 526 85.1 globlastp 1959 LNU74 arabidopsis|gb165|AT4G27090 3776 526 85.1 globlastp 1960 LNU74 b_oleracea|gb161|DY025895 3777 526 85.1 globlastp 1961 LNU74 cowpea|gb166|FF393525 3778 526 85.1 globlastp 1962 LNU74 nuphar|gb166|CD475921 3779 526 85.1 globlastp 1963 LNU74 oil_palm|gb166|EL689892 3780 526 85.1 globlastp 1964 LNU74 pepper|gb157.2|BM062339 3781 526 85.1 globlastp 1965 LNU74 pepper|gb171|BM062339 3781 526 85.1 globlastp 1966 LNU74 poppy|gb166|FE964687 3782 526 85.1 globlastp 1967 LNU74 tobacco|gb162|BQ842878 3783 526 85.1 globlastp 1968 LNU74 tobacco|gb162|BQ842898 3784 526 85.1 globlastp 1969 LNU74 tobacco|gb162|CV017540 3783 526 85.1 globlastp 1970 LNU74 antirrhinum|gb166|AJ786986 3785 526 85.07 glotblastn 1971 LNU74 soybean|gb168|AW171724 3786 526 84.33 glotblastn 1972 LNU74 arabidopsis_lyrata|09v1|JGIAL025381 3787 526 84.3 globlastp 1973 LNU74 flax|09v1|EU830250 3788 526 84.3 globlastp 1974 LNU74 ipomoea_nil|10v1|BJ554450 3789 526 84.3 globlastp 1975 LNU74 ipomoea_nil|10v1|BJ554544 3790 526 84.3 globlastp 1976 LNU74 avocado|10v1|CV460831 3791 526 84.3 globlastp 1977 LNU74 avocado|gb164|CV460831 3791 526 84.3 globlastp 1978 LNU74 avocado|gb164|CV461343 3792 526 84.3 globlastp 1979 LNU74 bean|gb167|CA904056 3793 526 84.3 globlastp 1980 LNU74 canola|10v1|EE451770 3794 526 84.3 globlastp 1981 LNU74 cotton|gb164|BE052734 3795 526 84.3 globlastp 1982 LNU74 ginger|gb164|DY352377 3796 526 84.3 globlastp 1983 LNU74 ipomoea|gb157.2|BJ554450 3789 526 84.3 globlastp 1984 LNU74 ipomoea|gb157.2|BJ554544 3790 526 84.3 globlastp 1985 LNU74 lettuce|gb157.2|DW145600 3797 526 84.3 globlastp 1986 LNU74 liriodendron|gb166|CK748217 3798 526 84.3 globlastp 1987 LNU74 maize|gb170|LLFL032821 3799 526 84.3 globlastp 1988 LNU74 onion|gb162|BQ579932 3800 526 84.3 globlastp 1989 LNU74 pepper|gb171|BM061235 3801 526 84.3 globlastp 1990 LNU74 pepper|gb157.2|CA521239 3802 526 84.3 globlastp 1991 LNU74 petunia|gb166|CV296857 3803 526 84.3 globlastp 1992 LNU74 petunia|gb171|CV296857 3803 526 84.3 globlastp 1993 LNU74 poppy|gb166|FE965604 3804 526 84.3 globlastp 1994 LNU74 rose|10v1|EC588002 3805 526 84.3 globlastp 1995 LNU74 rose|gb157.2|EC588002 3805 526 84.3 globlastp 1996 LNU74 strawberry|gb164|CO379805 3806 526 84.3 globlastp 1997 LNU74 triphysaria|gb164|EX996679 3807 526 84.3 globlastp 1998 LNU74 walnuts|gb166|EL900249 3808 526 84.3 globlastp 1999 LNU74 apple|gb171|CN444601 3809 526 83.6 globlastp 2000 LNU74 bean|gb167|CA897601 3810 526 83.6 globlastp 2001 LNU74 bean|gb167|CB543012 3811 526 83.6 globlastp 2002 LNU74 beet|gb162|BI095986 3812 526 83.6 globlastp 2003 LNU74 cowpea|gb166|FF385283 3813 526 83.6 globlastp 2004 LNU74 ipomoea|gb157.2|BU691765 3814 526 83.6 globlastp 2005 LNU74 lettuce|gb157.2|DW043837 3815 526 83.6 globlastp 2006 LNU74 lettuce|gb157.2|DW048497 3816 526 83.6 globlastp 2007 LNU74 lettuce|10v1|DW074549 3817 526 83.6 globlastp 2008 LNU74 lettuce|gb157.2|DW074549 3817 526 83.6 globlastp 2009 LNU74 lettuce|10v1|DW074794 3818 526 83.6 globlastp 2010 LNU74 lettuce|gb157.2|DW074794 3818 526 83.6 globlastp 2011 LNU74 lettuce|gb157.2|DW104050 3815 526 83.6 globlastp 2012 LNU74 lettuce|gb157.2|DW151136 3816 526 83.6 globlastp 2013 LNU74 lotus|09v1|CB827421 3819 526 83.6 globlastp 2014 LNU74 lotus|gb157.2|CB827421 3819 526 83.6 globlastp 2015 LNU74 pepper|gb157.2|BM061235 3820 526 83.6 globlastp 2016 LNU74 soybean|gb168|AL373135 3821 526 83.6 globlastp 2017 LNU74 soybean|gb168|CA904059 3822 526 83.6 globlastp 2018 LNU74 lettuce|10v1|DW043837 3815 526 83.6 globlastp 2019 LNU74 lettuce|10v1|DW048497 3816 526 83.6 globlastp 2020 LNU74 blueberry|10v1|CF811622 3823 526 83.58 glotblastn 2021 LNU74 arabidopsis_lyrata|09v1|JGIAL012515 3824 526 82.8 globlastp 2022 LNU74 cucumber|09v1|CK700738 3825 526 82.8 globlastp 2023 LNU74 bean|gb167|CA897605 3826 526 82.8 globlastp 2024 LNU74 cichorium|gb166|EH700721 3827 526 82.8 globlastp 2025 LNU74 cichorium|gb171|EH700721 3827 526 82.8 globlastp 2026 LNU74 clover|gb162|BB922889 3828 526 82.8 globlastp 2027 LNU74 coffea|10v1|DV665694 3829 526 82.8 globlastp 2028 LNU74 coffea|gb157.2|DV665694 3829 526 82.8 globlastp 2029 LNU74 eucalyptus|gb166|CT981369 3830 526 82.8 globlastp 2030 LNU74 lettuce|gb157.2|DW120158 3831 526 82.8 globlastp 2031 LNU74 lettuce|gb157.2|DW148342 3831 526 82.8 globlastp 2032 LNU74 nuphar|gb166|CK768054 3832 526 82.8 globlastp 2033 LNU74 prunus|gb167|BU040832 3833 526 82.8 globlastp 2034 LNU74 safflower|gb162|EL375831 3834 526 82.8 globlastp 2035 LNU74 soybean|gb168|AW719570 3835 526 82.8 globlastp 2036 LNU74 triphysaria|gb164|EX989915 3836 526 82.8 globlastp 2037 LNU74 lettuce|10v1|DW045707 3831 526 82.8 globlastp 2038 LNU74 cucumber|09v1|AB008846 3837 526 82.1 globlastp 2039 LNU74 gerbera|09v1|AJ758629 3838 526 82.1 globlastp 2040 LNU74 liquorice|gb171|FS241908 3839 526 82.1 globlastp 2041 LNU74 rose|10v1|EC586454 3840 526 82.1 globlastp 2042 LNU74 lettuce|gb157.2|DW045707 3841 526 82.1 globlastp 2043 LNU74 lotus|09v1|LLAW163943 3842 526 82.1 globlastp 2044 LNU74 lotus|gb157.2|AW163943 3842 526 82.1 globlastp 2045 LNU74 medicago|09v1|AJ388670 3843 526 82.1 globlastp 2046 LNU74 medicago|gb157.2|AJ388670 3843 526 82.1 globlastp 2047 LNU74 melon|gb165|DV635132 3837 526 82.1 globlastp 2048 LNU74 sunflower|gb162|CD849558 3844 526 82.1 globlastp 2049 LNU74 sunflower|gb162|CD850836 3845 526 82.1 globlastp 2050 LNU74 sunflower|gb162|CD853111 3846 526 82.1 globlastp 2051 LNU74 tobacco|gb162|EB443461 3847 526 82.1 globlastp 2052 LNU74 petunia|gb171|DC240554 3848 526 81.48 glotblastn 2053 LNU74 antirrhinum|gb166|AJ789125 3849 526 81.34 glotblastn 2054 LNU74 liriodendron|gb166|CK767651 3850 526 81.34 glotblastn 2055 LNU74 cucumber|09v1|AM720896 3851 526 81.3 globlastp 2056 LNU74 gerbera|09v1|AJ750902 3852 526 81.3 globlastp 2057 LNU74 gerbera|09v1|AJ752958 3853 526 81.3 globlastp 2058 LNU74 centaurea|gb166|EH740419 3854 526 81.3 globlastp 2059 LNU74 cynara|gb167|GE588148 3855 526 81.3 globlastp 2060 LNU74 dandelion|gb161|DY837376 3856 526 81.3 globlastp 2061 LNU74 iceplant|gb164|BE033656 3857 526 81.3 globlastp 2062 LNU74 melon|gb165|AM720896 3851 526 81.3 globlastp 2063 LNU74 melon|gb165|EB714459 3858 526 81.3 globlastp 2064 LNU74 peanut|gb171|EE125965 3859 526 81.3 globlastp 2065 LNU74 zamia|gb166|CB095897 3860 526 81.3 globlastp 2066 LNU74 chickpea|09v2|GR398973 3861 526 80.6 glotblastn 2067 LNU74 ginseng|10v1|CN846065 3862 526 80.6 globlastp 2068 LNU74 pea|09v1|PSU78952 3863 526 80.6 glotblastn 2069 LNU74 artemisia|gb164|EY050285 3864 526 80.6 globlastp 2070 LNU74 artemisia|gb164|EY052651 3865 526 80.6 globlastp 2071 LNU74 centaurea|gb166|EH737655 3866 526 80.6 globlastp 2072 LNU74 medicago|09v1|AW686970 3867 526 80.6 globlastp 2073 LNU74 medicago|gb157.2|AW686970 3867 526 80.6 globlastp 2074 LNU74 peanut|gb167|EE123818 3868 526 80.6 globlastp 2075 LNU74 peanut|gb171|EE123818 3868 526 80.6 globlastp 2076 LNU74 peanut|gb167|EE125965 3869 526 80.6 globlastp 2077 LNU74 petunia|gb166|EB174480 3870 526 80.6 glotblastn 2078 LNU74 spruce|gb162|CO234251 3871 526 80.6 globlastp 2079 LNU74 sunflower|gb162|CD851355 3872 526 80.6 globlastp 2080 LNU74 tobacco|gb162|EB444354 3873 526 80.6 globlastp 2081 LNU74 petunia|gb171|EB174480 3874 526 80.4 globlastp 2082 LNU75 soybean|gb168|BQ453397 3875 527 96.5 globlastp 2083 LNU75 bean|gb167|CB540681 3876 527 94.43 glotblastn 2084 LNU75 castorbean|gb160|MDL29647M002010 3877 527 83.3 globlastp 2085 LNU75 poplar|10v1|CV248257 3878 527 83.2 globlastp 2086 LNU75 poplar|gb170|CV248257 3878 527 83.2 globlastp 2087 LNU75 poplar|10v1|BU817503 3879 527 82.1 globlastp 2088 LNU75 poplar|gb170|BU817503 3879 527 82.1 globlastp 2089 LNU75 cassava|09v1|DB930644 3880 527 80.47 glotblastn 2090 LNU75 castorbean|09v1|EG661615 3881 527 80.4 globlastp 2091 LNU75 lotus|09v1|CRPLJ030481 3882 527 80.2 globlastp 2092 LNU76 brachypodium|09v1|DV474282 3883 528 91.8 globlastp 2093 LNU76 oat|10v1|SRR020741S0039710 3884 528 91.3 globlastp 2094 LNU76 wheat|gb164|BE213625 3885 528 91.3 globlastp 2095 LNU76 barley|gb157.3|AJ234439 3886 528 91 globlastp 2096 LNU76 barley|gb157SOLEXA|AJ234439 3886 528 91 globlastp 2097 LNU76 sorghum|09v1|SB07G028080 3887 528 89.8 globlastp 2098 LNU76 sorghum|gb161.crp|AW283835 3887 528 89.8 globlastp 2099 LNU76 switchgrass|gb167|DN147961 3888 528 89.1 globlastp 2100 LNU76 maize|gb170|BI431326 3889 528 88.3 globlastp 2101 LNU76 ipomoea_nil|10v1|BJ557425 3890 528 87.8 globlastp 2102 LNU76 ipomoea|gb157.2|BM878831 3890 528 87.8 globlastp 2103 LNU76 tobacco|gb162|DV159853 3891 528 87.6 globlastp 2104 LNU76 eggplant|10v1|FS024720XX1 3892 528 87.3 globlastp 2105 LNU76 pepper|gb171|BM064103 3893 528 87.3 globlastp 2106 LNU76 chestnut|gb170|SRR006295S0084519 3894 528 87.3 globlastp 2107 LNU76 solanum_phureja|09v1|SPHAA824694 3895 528 87.1 globlastp 2108 LNU76 castorbean|09v1|EE254059 3896 528 87.1 globlastp 2109 LNU76 castorbean|gb160|EE254059 3896 528 87.1 globlastp 2110 LNU76 maize|gb170|SRR014549S0042197 3897 528 87.1 glotblastn 2111 LNU76 tomato|gb164|AA824694 3898 528 87.1 globlastp 2112 LNU76 nicotiana_benthamiana|gb162| 3899 528 87.06 glotblastn CN741775 2113 LNU76 maize|gb170|BE640543 3900 528 86.85 glotblastn 2114 LNU76 cassava|09v1|CK641674 3901 528 86.8 globlastp 2115 LNU76 potato|gb157.2|BG096473 3902 528 86.8 globlastp 2116 LNU76 cleome_spinosa|10v1|SRR015531S0001775 3903 528 86.6 globlastp 2117 LNU76 aquilegia|10v1|DR924828 3904 528 86.6 globlastp 2118 LNU76 aquilegia|gb157.3|DR924828 3904 528 86.6 globlastp 2119 LNU76 medicago|09v1|AW698676 3905 528 86.6 globlastp 2120 LNU76 medicago|gb157.2|AW127555 3905 528 86.6 globlastp 2121 LNU76 melon|gb165|AF461048 3906 528 86.6 globlastp 2122 LNU76 potato|gb157.2|BE919491 3907 528 86.6 globlastp 2123 LNU76 pseudoroegneria|gb167|FF361372 3908 528 86.6 globlastp 2124 LNU76 potato|10v1|BG096473 3909 528 86.57 glotblastn 2125 LNU76 potato|10v1|BE919491 3910 528 86.32 glotblastn 2126 LNU76 cassava|09v1|CK641556 3911 528 86.3 globlastp 2127 LNU76 cucumber|09v1|AF461048 3912 528 86.3 globlastp 2128 LNU76 leymus|gb166|EG397002 3913 528 86.3 globlastp 2129 LNU76 melon|gb165|AY066012 3914 528 86.3 globlastp 2130 LNU76 triphysaria|gb164|EX982271 3915 528 86.3 globlastp 2131 LNU76 cleome_gynandra|10v1|SRR015532S0001935 3916 528 86.1 globlastp 2132 LNU76 cucumber|09v1|AY066012 3917 528 85.8 globlastp 2133 LNU76 apple|gb157.3|CN488454 3918 528 85.8 globlastp 2134 LNU76 apple|gb171|CN488454 3918 528 85.8 globlastp 2135 LNU76 apple|gb157.3|CN489537 3919 528 85.8 globlastp 2136 LNU76 apple|gb171|CN489537 3919 528 85.8 globlastp 2137 LNU76 b_oleracea|gb161|AM394032 3920 528 85.8 globlastp 2138 LNU76 canola|gb161|BQ704207 3920 528 85.8 globlastp 2139 LNU76 clover|gb162|BB932727 3921 528 85.8 globlastp 2140 LNU76 papaya|gb165|EX241410 3922 528 85.8 globlastp 2141 LNU76 peanut|gb167|ES752188 3923 528 85.8 globlastp 2142 LNU76 peanut|gb171|ES752188 3923 528 85.8 globlastp 2143 LNU76 chickpea|09v2|DY475133 3924 528 85.6 globlastp 2144 LNU76 b_juncea|gb164|EVGN00028714050635 3925 528 85.6 globlastp 2145 LNU76 b_rapa|gb162|CX272671 3926 528 85.6 globlastp 2146 LNU76 canola|10v1|CB686087 3926 528 85.6 globlastp 2147 LNU76 canola|gb161|CB686087 3926 528 85.6 globlastp 2148 LNU76 cichorium|gb171|EH672667 3927 528 85.6 globlastp 2149 LNU76 cotton|gb164|CO072567 3928 528 85.6 globlastp 2150 LNU76 ginger|gb164|DY344931 3929 528 85.6 globlastp 2151 LNU76 lettuce|gb157.2|DW047667 3930 528 85.6 globlastp 2152 LNU76 lettuce|gb157.2|DW101545 3930 528 85.6 globlastp 2153 LNU76 lettuce|gb157.2|DW146107 3930 528 85.6 globlastp 2154 LNU76 walnuts|gb166|EL891302 3931 528 85.6 globlastp 2155 LNU76 lettuce|10v1|DW047667 3930 528 85.6 globlastp 2156 LNU76 eucalyptus|gb166|CD668235 3932 528 85.57 glotblastn 2157 LNU76 lotus|09v1|AI967569 3933 528 85.3 globlastp 2158 LNU76 citrus|gb166|CF417173 3934 528 85.3 globlastp 2159 LNU76 cotton|gb164|CA993018 3935 528 85.3 globlastp 2160 LNU76 sunflower|gb162|CD845667 3936 528 85.3 globlastp 2161 LNU76 thellungiella|gb167|DN772880 3937 528 85.3 globlastp 2162 LNU76 artemisia|gb164|EY032115 3938 528 85.1 globlastp 2163 LNU76 b_rapa|gb162|BG544512 3939 528 85.1 globlastp 2164 LNU76 canola|10v1|BQ704676 3940 528 85.1 globlastp 2165 LNU76 canola|gb161|CX191423 3940 528 85.1 globlastp 2166 LNU76 poplar|10v1|BI068844 3941 528 85.1 globlastp 2167 LNU76 poplar|gb170|BI068844 3942 528 85.1 globlastp 2168 LNU76 poplar|10v1|BI069243 3943 528 85.1 globlastp 2169 LNU76 poplar|gb170|BI069243 3943 528 85.1 globlastp 2170 LNU76 radish|gb164|EV525299 3944 528 85.1 globlastp 2171 LNU76 banana|gb167|DN238082 3945 528 85.07 glotblastn 2172 LNU76 cichorium|gb166|EH672667 3946 528 85.07 glotblastn 2173 LNU76 b_oleracea|gb161|AM385579 3947 528 84.8 globlastp 2174 LNU76 coffea|10v1|DV678645 3948 528 84.8 globlastp 2175 LNU76 coffea|gb157.2|DV678645 3948 528 84.8 globlastp 2176 LNU76 cowpea|gb166|FC456675 3949 528 84.8 globlastp 2177 LNU76 cleome_gynandra|10v1|SRR015532S0005303 3950 528 84.6 globlastp 2178 LNU76 prunus|gb167|BU039541 3951 528 84.6 globlastp 2179 LNU76 strawberry|gb164|DY667189 3952 528 84.6 globlastp 2180 LNU76 ginger|gb164|DY344881 3953 528 84.3 globlastp 2181 LNU76 iceplant|gb164|AA842895 3954 528 84.3 globlastp 2182 LNU76 soybean|gb168|AI967569 3955 528 84.3 globlastp 2183 LNU76 arabidopsis|gb165|AT2G13360 3956 528 84.1 globlastp 2184 LNU76 bean|gb167|GFXEU018611X1 3957 528 84.1 globlastp 2185 LNU76 safflower|gb162|EL384125 3958 528 84.08 glotblastn 2186 LNU76 arabidopsis_lyrata|09v1|JGIAL011701 3959 528 83.8 globlastp 2187 LNU76 soybean|gb168|AW719840 3960 528 83.3 globlastp 2188 LNU76 lotus|09v1|AW719840 3961 528 82.8 globlastp 2189 LNU76 lotus|gb157.2|AW719840 3962 528 82.6 globlastp 2190 LNU76 grape|gb160|BM436787 3963 528 82.3 globlastp 2191 LNU76 spruce|gb162|CO230132 3964 528 81.1 globlastp 2192 LNU76 centaurea|gb166|EL931044 3965 528 81.09 glotblastn 2193 LNU76 pine|10v1|CF476545 3966 528 80.4 globlastp 2194 LNU76 pine|gb157.2|CF476545 3966 528 80.4 globlastp 2195 LNU79 cacao|gb167|CU499480 3967 529 82.8 globlastp 2196 LNU83 soybean|gb168|BI974032 3968 532 80.5 globlastp 2197 LNU85 sugarcane|10v1|BQ529864 3969 534 98.3 globlastp 2198 LNU85 sugarcane|gb157.3|BQ529864 3969 534 98.3 globlastp 2199 LNU85 maize|gb170|AI941787 3970 534 94.1 globlastp 2200 LNU85 switchgrass|gb167|DN152416 3971 534 91.4 globlastp 2201 LNU85 millet|09v1|EVO454PM001540 3972 534 89.9 globlastp 2202 LNU85 rice|gb170|OS05G48450 3973 534 88.8 globlastp 2203 LNU85 barley|gb157.3|BI954412 3974 534 86.6 globlastp 2204 LNU85 barley|gb157SOLEXA|BI954412 3974 534 86.6 globlastp 2205 LNU85 brachypodium|09v1|GT758786 3975 534 86.6 globlastp 2206 LNU85 wheat|gb164|BE427293 3976 534 84.9 globlastp 2207 LNU85 rice|gb170|OS10G40200 3977 534 81.7 globlastp 2208 LNU85 brachypodium|gb169|BE402800 3978 534 81.4 globlastp 2209 LNU85 switchgrass|gb167|FE658951 3979 534 80.6 globlastp 2210 LNU85 brachypodium|09v1|SRR031795S0009845 3980 534 80 globlastp 2211 LNU86 sorghum|09v1|SB09G029470 3981 535 85.4 globlastp 2212 LNU86 sorghum|gb161.crp|AI941972 3981 535 85.4 globlastp 2213 LNU89 wheat|gb164|BG606995 3982 537 98.7 globlastp 2214 LNU89 rice|gb170|OS12G16350 3983 537 82.4 globlastp 2215 LNU94 solanum_phureja|09v1|SPHAW621975 3984 538 96.4 globlastp 2216 LNU94 solanum_phureja|09v1|SPHDV105556 3985 538 94.7 globlastp 2217 LNU94 potato|10v1|X98891 3986 538 93.8 globlastp 2218 LNU94 potato|gb157.2|X98891 3986 538 93.8 globlastp 2219 LNU94 pepper|gb171|EF091665 3987 538 90.5 globlastp 2220 LNU94 tobacco|gb162|AB042951 3988 538 88.4 globlastp 2221 LNU94 pepper|gb157.2|EF091665 3989 538 87.3 globlastp 2222 LNU94 cichorium|gb171|DT213190 3990 538 81.44 glotblastn 2223 LNU94 cichorium|gb166|DT213190 3991 538 80.49 glotblastn 2224 LNU94 medicago|09v1|MTAF000354 3992 538 80.37 glotblastn 2225 LNU94 medicago|gb157.2|MTAF000354 3992 538 80.37 glotblastn 2226 LNU94 solanum_phureja|09v1|SPHY16125 3993 538 80.34 glotblastn 2227 LNU94 potato|10v1|AF156695 3993 538 80.34 glotblastn 2228 LNU94 potato|gb157.2|AF156695 3993 538 80.34 glotblastn 2229 LNU94 lettuce|10v1|DW051651 3994 538 80.3 glotblastn 2230 LNU94 lettuce|gb157.2|DW051651 3994 538 80.3 glotblastn 2231 LNU94 medicago|09v1|AW329601 3995 538 80.19 glotblastn 2232 LNU94 medicago|09v1|MTAF000355 3996 538 80.15 glotblastn 2233 LNU94 medicago|gb157.2|MTAF000355 3996 538 80.15 glotblastn 2234 LNU95 bean|gb167|CV543264 3997 539 84.1 globlastp 2235 LNU95 cowpea|gb166|FF384522 3998 539 82.2 globlastp 2236 LNU100 cotton|gb164|BG440037 3999 542 91.97 glotblastn 2237 LNU100 strawberry|gb164|EX657249 4000 542 82.95 glotblastn 2238 LNU100 cassava|09v1|DB921063 4001 542 82.9 globlastp 2239 LNU100 poplar|gb170|BI069411 4002 542 82.3 globlastp 2240 LNU100 poplar|gb170|BI131061 4003 542 82.1 globlastp 2241 LNU100 chestnut|gb170|SRR006295S0057433 4004 542 81.97 glotblastn 2242 LNU100 citrus|gb166|BQ624837 4005 542 81.89 glotblastn 2243 LNU100 poplar|10v1|BI131061 4006 542 81.3 globlastp 2244 LNU100 cowpea|gb166|FF394721 4007 542 80.25 glotblastn 2245 LNU100 soybean|gb168|AW163881 4008 542 80.25 glotblastn 2246 LNU100 cucumber|09v1|CK756513 4009 542 80.2 globlastp 2247 LNU100 bean|gb167|CA901142 4010 542 80.2 globlastp 2248 LNU100 medicago|09v1|AL369478 4011 542 80.04 glotblastn 2249 LNU100 medicago|09v1|AW691643 4012 542 80 globlastp 2250 LNU104 soybean|gb168|BG647792 4013 544 95.5 globlastp 2251 LNU104 cowpea|gb166|FF382988 4014 544 89.8 globlastp 2252 LNU104 medicago|09v1|BG647792 4015 544 82.8 globlastp 2253 LNU104 medicago|gb157.2|BG647792 4016 544 82 glotblastn 2254 LNU105 leymus|gb166|EG396306 4017 545 95.8 globlastp 2254 LNU72 leymus|gb166|EG396306 4017 725 94.2 globlastp 2255 LNU105 pseudoroegneria|gb167|FF352468 4018 545 94.2 globlastp 2255 LNU72 pseudoroegneria|gb167|FF352468 4018 725 92.7 globlastp 2256 LNU105 oat|10v1|CN819266 4019 545 88.8 globlastp 2256 LNU72 oat|10v1|CN819266 4019 725 88.4 globlastp 2257 LNU106 wheat|gb164|BE426509 4020 546 98.2 globlastp 2258 LNU106 barley|gb157.3|AJ234436 4021 546 91.9 globlastp 2259 LNU106 barley|gb157SOLEXA|AJ234436 4021 546 91.9 globlastp 2260 LNU107 brachypodium|09v1|SRR031795S0019801 4022 547 83.9 globlastp 2261 LNU107 brachypodium|gb169|BE637729 4022 547 83.9 globlastp 2262 LNU107 wheat|gb164|BE637729 4023 547 82.89 glotblastn 2263 LNU109 sorghum|09v1|SB10G000960 4024 548 85.6 globlastp 2264 LNU109 sorghum|gb161.crp|AW286123 4024 548 85.6 globlastp 2265 LNU109 brachypodium|09v1|GT863831 4025 548 85.2 globlastp 2266 LNU109 brachypodium|gb169|BE443129 4025 548 85.2 globlastp 2267 LNU109 pseudoroegneria|gb167|FF364297 4026 548 81.3 globlastp 2268 LNU115 sugarcane|10v1|CA067152 4027 553 84.3 globlastp 2269 LNU115 sugarcane|gb157.3|CA067152 4028 553 84.2 globlastp 2270 LNU115 sorghum|09v1|SB07G004420 4029 553 84.1 globlastp 2271 LNU115 maize|gb170|AW067055 4030 553 83.9 globlastp 2272 LNU115 brachypodium|09v1|TMPLOS03G48850T1 4031 553 80.09 glotblastn 2273 LNU115 rice|gb170|OS03G48850 4031 553 80.09 glotblastn 2274 LNU116 sorghum|09v1|SB01G021870 4032 554 80.2 globlastp 2275 LNU121 sorghum|gb161.crp|CF060003 4033 559 80.7 globlastp 2276 LNU121 brachypodium|gb169|BE601610 4034 559 80.39 glotblastn 2277 LNU123 arabidopsis_lyrata|09v1|GFXDQ132362X1 4035 561 98.5 globlastp 2278 LNU124 arabidopsis_lyrata|09v1|JGIAL029920 4036 562 99.3 globlastp 2279 LNU124 radish|gb164|FD967528 4037 562 83.03 glotblastn 2280 LNU124 citrus|gb166|CV885509 4038 562 81.08 glotblastn 2281 LNU124 poplar|10v1|CX176510 4039 562 80.72 glotblastn 2282 LNU124 poplar|gb170|CX176510 4039 562 80.72 glotblastn 2283 LNU126 arabidopsis_lyrata|09v1|JGIAL030477 4040 563 94.2 globlastp 2284 LNU126 canola|10v1|EE444561 4041 563 83.6 globlastp 2285 LNU126 b_rapa|gb162|DN964586 4042 563 83.6 glotblastn 2286 LNU126 canola|gb161|EE444561 4043 563 83.6 glotblastn 2287 LNU126 radish|gb164|EX747028 4044 563 81.94 glotblastn 2288 LNU126 b_juncea|gb164|EVGN00669227830274P1 4045 563 80.5 globlastp 2289 LNU127 arabidopsis_lyrata|09v1|JGIAL030813 4046 564 91.4 globlastp 2290 LNU127 thellungiella|gb167|DN772829 4047 564 81.2 globlastp 2291 LNU128 arabidopsis_lyrata|09v1|JGIAL002292 4048 565 98.8 globlastp 2292 LNU130 arabidopsis_lyrata|09v1|JGIAL007931 4049 567 86.6 globlastp 2293 LNU131 arabidopsis_lyrata|09v1|JGIAL015515 4050 568 92.9 globlastp 2294 LNU131 b_oleracea|gb161|DY026439 4051 568 82.7 globlastp 2295 LNU131 canola|gb161|DY023887 4052 568 82.33 glotblastn 2296 LNU131 canola|10v1|ES956350 4053 568 81.95 glotblastn 2297 LNU131 canola|10v1|DY023887 4054 568 80.6 glotblastn 2298 LNU131 radish|gb164|EW731027 4055 568 80.37 glotblastn 2299 LNU131 radish|gb164|EV546624 4056 568 80 glotblastn 2300 LNU132 arabidopsis_lyrata|09v1|JGIAL007040 4057 569 94.5 globlastp 2301 LNU133 arabidopsis_lyrata|09v1|JGIAL007458 4058 570 95.9 globlastp 2302 LNU133 canola|10v1|EE426894 4059 570 87.8 globlastp 2303 LNU133 canola|gb161|CX193266 4059 570 87.8 globlastp 2304 LNU133 b_rapa|gb162|CV434022 4060 570 86.7 globlastp 2305 LNU133 canola|gb161|CD830045 4061 570 86.7 globlastp 2306 LNU133 radish|gb164|EV527818 4062 570 86.7 globlastp 2307 LNU133 b_oleracea|gb161|AM057011 4063 570 85.7 globlastp 2308 LNU133 b_oleracea|gb161|ES948067 4064 570 85.7 globlastp 2309 LNU133 b_rapa|gb162|EE516981 4065 570 85.7 globlastp 2310 LNU133 canola|gb161|CD822076 4066 570 85.7 globlastp 2311 LNU133 canola|10v1|CX193266 4063 570 85.7 globlastp 2312 LNU133 canola|gb161|CX193799 4063 570 85.7 globlastp 2313 LNU133 radish|gb164|EW725954 4067 570 85.7 globlastp 2314 LNU133 radish|gb164|EW729334 4068 570 85.7 globlastp 2315 LNU133 radish|gb164|EX770388 4068 570 85.7 globlastp 2316 LNU133 radish|gb164|EX774120 4068 570 85.7 globlastp 2317 LNU133 b_juncea|gb164|EVGN00336011243437 4069 570 83.7 globlastp 2318 LNU133 b_juncea|gb164|EVGN00782708352054 4070 570 83.7 globlastp 2319 LNU133 b_oleracea|gb161|AM060067 4069 570 83.7 globlastp 2320 LNU133 b_rapa|gb162|CX266396 4069 570 83.7 globlastp 2321 LNU133 canola|10v1|BQ704992 4069 570 83.7 globlastp 2322 LNU133 canola|gb161|BQ704992 4069 570 83.7 globlastp 2323 LNU133 canola|10v1|H07830 4069 570 83.7 globlastp 2324 LNU133 canola|gb161|H07830 4069 570 83.7 globlastp 2325 LNU133 radish|gb164|EV527349 4069 570 83.7 globlastp 2326 LNU133 radish|gb164|EV535700 4069 570 83.7 globlastp 2327 LNU133 radish|gb164|EV568761 4069 570 83.7 globlastp 2328 LNU133 radish|gb164|EX747596 4069 570 83.7 globlastp 2329 LNU133 radish|gb164|FD538859 4071 570 82.7 globlastp 2330 LNU133 thellungiella|gb167|DN775946 4072 570 82.7 globlastp 2331 LNU133 b_rapa|gb162|EX025487 4073 570 82.47 glotblastn 2332 LNU133 radish|gb164|EV545406 4074 570 82.47 glotblastn 2333 LNU133 radish|gb164|FD981399 4075 570 81.44 glotblastn 2334 LNU134 arabidopsis_lyrata|09v1|JGIAL023230 4076 571 92.8 globlastp 2335 LNU136 arabidopsis_lyrata|09v1|JGIAL016753 4077 573 94.8 globlastp 2336 LNU136 canola|10v1|EV117254 4078 573 83.71 glotblastn 2337 LNU138 wheat|gb164|BE404910 4079 574 98.4 globlastp 2338 LNU138 pseudoroegneria|gb167|FF343940 4080 574 97.5 globlastp 2339 LNU138 wheat|gb164|BE405302 4081 574 97.2 globlastp 2340 LNU138 oat|10v1|GR335867 4082 574 91.5 globlastp 2341 LNU138 brachypodium|09v1|DV481179 4083 574 87.4 globlastp 2342 LNU138 brachypodium|gb169|BE404910 4084 574 83.91 glotblastn 2343 LNU138 rice|gb170|OS05G31750 4085 574 80.6 globlastp 2344 LNU140 canola|gb161|ES899922 4086 575 92.4 globlastp 2345 LNU141 barley|gb157.3|AV832506 4087 576 80.6 globlastp 2346 LNU141 barley|gb157SOLEXA|AV832506 4087 576 80.6 globlastp 2347 LNU142 wheat|gb164|BE429302 4088 577 88.1 globlastp 2348 LNU143 cotton|gb164|BQ411539 4089 578 83.63 glotblastn 2349 LNU147 heritiera|10v1|SRR005795S0005739 4090 580 83.8 globlastp 2350 LNU147 cacao|gb167|CU470446 4091 580 83.1 globlastp 2351 LNU148 soybean|gb168|CD399473 4092 581 87.7 globlastp 2352 LNU148 cowpea|gb166|FG822996 4093 581 81.5 globlastp 2353 LNU150 antirrhinum|gb166|AJ787462 4094 583 84.8 globlastp 2354 LNU153 switchgrass|gb167|FE648089 4095 584 91.8 globlastp 2355 LNU153 wheat|gb164|CA499728 4096 584 91.5 globlastp 2356 LNU153 sorghum|09v1|SB09G000910 4097 584 91.3 globlastp 2357 LNU153 sorghum|gb161.crp|AW564938 4097 584 91.3 globlastp 2358 LNU153 maize|gb170|AW787777 4098 584 89.5 globlastp 2359 LNU153 oat|10v1|GR331123 4099 584 89.08 glotblastn 2360 LNU153 switchgrass|gb167|FL747998 4100 584 85 globlastp 2361 LNU153 switchgrass|gb167|FL711487 4101 584 84.6 globlastp 2362 LNU153 brachypodium|09v1|DV482357 4102 584 84.4 globlastp 2363 LNU153 brachypodium|gb169|BE420118 4102 584 84.4 globlastp 2364 LNU153 rice|gb170|OS01G73970 4103 584 84.3 globlastp 2365 LNU153 barley|gb157SOLEXA|BI959596 4104 584 82.9 globlastp 2366 LNU153 sorghum|09v1|SB03G047280 4105 584 82.8 globlastp 2367 LNU153 sorghum|gb161.crp|BI139689 4105 584 82.8 globlastp 2368 LNU153 barley|gb157.3|BI959596 4106 584 82.6 globlastp 2369 LNU153 ginger|gb164|DY353392 4107 584 80.6 globlastp 2370 LNU157 soybean|gb168|AL365749 4108 587 96.5 globlastp 2371 LNU157 bean|gb167|CB540562 4109 587 93 globlastp 2372 LNU157 medicago|09v1|AW299124 4110 587 85.7 globlastp 2373 LNU161 soybean|gb168|CF808044 4111 589 88.8 globlastp 2374 LNU161 cowpea|gb166|FG846783 4112 589 80.8 globlastp 2375 LNU168 maize|gb170|AW927746 4113 590 97.2 globlastp 2376 LNU168 sugarcane|gb157.3|CA098262 4114 590 97.2 globlastp 2377 LNU168 sugarcane|10v1|BU102716 4114 590 97.2 globlastp 2378 LNU168 sugarcane|gb157.3|BU102716 4115 590 91.59 glotblastn 2379 LNU168 switchgrass|gb167|FL875098 4116 590 83.6 globlastp 2380 LNU168 switchgrass|gb167|DN151126 4117 590 82.7 globlastp 2381 LNU171 wheat|gb164|CK211341 4118 592 88.1 globlastp 2382 LNU171 wheat|gb164|CA712412 4119 592 85.3 globlastp 2383 LNU171 barley|gb157.3|BQ740207 4120 592 83.1 globlastp 2384 LNU171 barley|gb157SOLEXA|BQ740207 4120 592 83.1 globlastp 2385 LNU171 wheat|gb164|BE415592 4121 592 82.39 glotblastn 2386 LNU173 wheat|gb164|BE213263 4122 594 90.8 globlastp 2387 LNU173 wheat|gb164|BG607192 4123 594 90.2 globlastp 2388 LNU173 oat|10v1|Z48431 4124 594 80.3 globlastp 2389 LNU175 arabidopsis_lyrata|09v1|JGIAL025246 4125 595 92.5 globlastp 2390 LNU175 canola|10v1|CD820948 4126 595 85 globlastp 2391 LNU175 canola|gb161|CD820948 4126 595 85 globlastp 2392 LNU175 radish|gb164|EW731834 4126 595 85 globlastp 2393 LNU176 rice|gb170|OS07G23570 4127 596 85.7 globlastp 2394 LNU176 rice|gb170|OS07G44110 4128 596 81.6 globlastp 2395 LNU177 arabidopsis_lyrata|09v1|JGIAL006953 4129 597 95.2 globlastp 2396 LNU177 radish|gb164|EY932302 4130 597 81.3 globlastp 2397 LNU177 canola|10v1|BQ705039 4131 597 80.6 globlastp 2398 LNU177 canola|10v1|CN728969 4132 597 80.4 globlastp 2399 LNU177 canola|gb161|CN728969 4132 597 80.4 globlastp 2400 LNU177 b_oleracea|gb161|DY018716 4133 597 80.1 globlastp 2401 LNU177 b_rapa|gb162|EX061625 4134 597 80.1 globlastp 2402 LNU177 canola|gb161|BQ705039 4135 597 80.1 globlastp 2403 LNU178 arabidopsis_lyrata|09v1|JGIAL001921 4136 598 97.6 globlastp 2404 LNU178 canola|10v1|EE542748 4137 598 86.06 glotblastn 2405 LNU178 b_rapa|gb162|DN960788 4138 598 84.3 globlastp 2406 LNU178 canola|gb161|EL592266 4139 598 84.3 globlastp 2407 LNU178 radish|gb164|EV566211 4140 598 84.06 glotblastn 2408 LNU178 canola|10v1|EL592266 4141 598 83.8 globlastp 2409 LNU178 b_rapa|gb162|DN961047 4142 598 83.3 globlastp 2410 LNU178 radish|gb164|EX897481 4143 598 83.1 globlastp 2411 LNU180 arabidopsis_lyrata|09v1|JGIAL007244 4144 600 87.8 globlastp 2412 LNU181 arabidopsis_lyrata|09v1|JGIAL019086 4145 601 97.3 globlastp 2413 LNU181 arabidopsis|gb165|AT1G10490 4146 601 84.1 globlastp 2414 LNU181 arabidopsis_lyrata|09v1|JGIAL001043 4147 601 82.6 globlastp 2415 LNU182 arabidopsis_lyrata|09v1|JGIAL009295 4148 602 97.4 globlastp 2416 LNU182 canola|10v1|CD838490 4149 602 89 globlastp 2417 LNU182 canola|gb161|CD838490 4149 602 89 globlastp 2418 LNU182 thellungiella|gb167|BY804904 4150 602 87.7 globlastp 2419 LNU182 radish|gb164|EX905824 4151 602 87.1 globlastp 2420 LNU182 canola|10v1|ES915047 4152 602 87 globlastp 2421 LNU182 canola|gb161|ES915047 4152 602 87 globlastp 2422 LNU183 arabidopsis_lyrata|09v1|JGIAL006103 4153 603 96.2 globlastp 2423 LNU184 arabidopsis_lyrata|09v1|JGIAL018440 4154 604 88.4 globlastp 2424 LNU185 arabidopsis_lyrata|09v1|JGIAL019672 4155 605 91.3 globlastp 2425 LNU185 thellungiella|gb167|BM985521 4156 605 80 globlastp 2426 LNU186 arabidopsis_lyrata|09v1|BQ834224 4157 606 98.9 globlastp 2427 LNU186 canola|10v1|EE466406 4158 606 96.6 globlastp 2428 LNU186 b_rapa|gb162|EX032398 4159 606 96.1 globlastp 2429 LNU186 canola|gb161|EE466406 4160 606 96.1 globlastp 2430 LNU186 canola|10v1|CN730049 4161 606 95 globlastp 2431 LNU186 canola|gb161|CN730049 4161 606 95 globlastp 2432 LNU186 radish|gb164|EW725004 4162 606 94.4 globlastp 2433 LNU186 radish|gb164|EX746993 4162 606 94.4 globlastp 2434 LNU186 radish|gb164|EX755385 4162 606 94.4 globlastp 2435 LNU186 radish|gb164|EX763493 4163 606 93.9 globlastp 2436 LNU186 b_rapa|gb162|L38047 4164 606 93.3 globlastp 2437 LNU186 radish|gb164|EY911865 4165 606 93.3 globlastp 2438 LNU186 cleome_gynandra|10v1|SRR015532S0005426 4166 606 88.3 globlastp 2439 LNU186 cleome_spinosa|10v1|GR931536 4167 606 88.3 globlastp 2440 LNU186 cotton|gb164|BQ403404 4168 606 81 globlastp 2441 LNU186 cacao|gb167|CU485964 4169 606 80.4 globlastp 2442 LNU186 cotton|gb164|AI728654 4170 606 80.4 globlastp 2443 LNU187 arabidopsis_lyrata|09v1|JGIAL019765 4171 607 92.4 globlastp 2444 LNU188 soybean|gb168|BE661293 4172 608 90.9 globlastp 2445 LNU188 bean|gb167|FE696342 4173 608 80.24 glotblastn 2446 LNU190 b_oleracea|gb161|AM388062 4174 610 96.7 globlastp 2447 LNU190 canola|gb161|EV105578 4175 610 94.8 globlastp 2448 LNU190 radish|gb164|EV544043 4176 610 90.2 globlastp 2449 LNU192 sorghum|09v1|SB09G029740 4177 612 92.9 globlastp 2450 LNU192 brachypodium|gb169|BE406170 4178 612 90 globlastp 2451 LNU192 brachypodium|09v1|GT839119 4179 612 85.9 globlastp 2452 LNU192 sorghum|gb161.crp|AW747561 4180 612 82.5 globlastp 2453 LNU200 potato|10v1|BQ513965 4181 615 95.9 globlastp 2454 LNU200 potato|gb157.2|BQ513965 4182 615 95.3 globlastp 2455 LNU200 solanum_phureja|09v1|SPHBG791292 4183 615 93.8 globlastp 2456 LNU200 eggplant|10v1|FS057436 4184 615 92.1 globlastp 2457 LNU200 tobacco|gb162|DW002634 4185 615 87.7 globlastp 2458 LNU206 arabidopsis_lyrata|09v1|JGIAL014285 4186 617 93.3 globlastp 2459 LNU207 arabidopsis_lyrata|09v1|JGIAL007246 4187 618 94.9 globlastp 2460 LNU207 canola|10v1|H07749 4188 618 84.8 globlastp 2461 LNU207 canola|gb161|H07749 4188 618 84.8 globlastp 2462 LNU210 arabidopsis_lyrata|09v1|JGIAL019410 4189 619 94.1 globlastp 2463 LNU210 canola|10v1|EG019929 4190 619 85.86 glotblastn 2464 LNU210 canola|gb161|EG019929 4191 619 85.6 globlastp 2465 LNU210 radish|gb164|EW715949 4192 619 81.4 globlastp 2466 LNU211 arabidopsis_lyrata|09v1|JGIAL020302 4193 620 97.5 globlastp 2467 LNU211 thellungiella|gb167|BY811489 4194 620 96.7 globlastp 2468 LNU211 canola|10v1|EE452044 4195 620 90.2 globlastp 2469 LNU211 canola|10v1|EE465088 4196 620 90.2 globlastp 2470 LNU211 canola|gb161|EE465088 4196 620 90.2 globlastp 2471 LNU211 radish|gb164|EX746074 4195 620 90.2 globlastp 2472 LNU211 b_rapa|gb162|CV545795 4197 620 89.4 globlastp 2473 LNU211 canola|10v1|ES923006 4197 620 89.4 globlastp 2474 LNU211 canola|gb161|EE452044 4197 620 89.4 globlastp 2475 LNU211 canola|10v1|EE429968 4198 620 88.5 globlastp 2476 LNU211 canola|gb161|EE429968 4198 620 88.5 globlastp 2477 LNU211 b_rapa|gb162|BG544555 4199 620 86.89 glotblastn 2478 LNU211 b_rapa|gb162|CX269583 4200 620 86.89 glotblastn 2479 LNU214 canola|10v1|DV643275 4201 623 83 globlastp 2480 LNU214 canola|gb161|DV643275 4201 623 83 globlastp 2481 LNU214 b_oleracea|gb161|AM057785 4202 623 80.7 globlastp 2482 LNU215 arabidopsis_lyrata|09v1|JGIAL000823 4203 624 93.9 globlastp 2483 LNU215 canola|10v1|CD837114 4204 624 81.3 globlastp 2484 LNU215 radish|gb164|EX902620 4205 624 80.1 globlastp 2485 LNU216 rice|gb170|OS12G05440 4206 625 85.6 globlastp 2486 LNU216 maize|gb170|LLCF001713 4207 625 81.4 globlastp 2487 LNU216 sorghum|09v1|SB05G003100 4208 625 80.27 glotblastn 2488 LNU216 sorghum|gb161.crp|BG048909 4208 625 80.27 glotblastn 2489 LNU216 sorghum|09v1|SB08G003110 4209 625 80.1 globlastp 2490 LNU216 sorghum|gb161.crp|BE918845 4209 625 80.1 globlastp 2491 LNU216 maize|gb170|CA404041 4210 625 80 globlastp 2492 LNU218 arabidopsis_lyrata|09v1|JGIAL027135 4211 627 95.8 globlastp 2493 LNU218 canola|gb161|CD836926 4212 627 91.7 globlastp 2494 LNU218 radish|gb164|EW725001 4213 627 89.6 globlastp 2495 LNU218 castorbean|09v1|XM002514040 4214 627 81.35 glotblastn 2496 LNU218 castorbean|gb160|MDL29912M005300 4214 627 81.35 glotblastn 2497 LNU218 grape|gb160|BQ792882 4215 627 80.68 glotblastn 2498 LNU218 citrus|gb166|CN191381 4216 627 80.58 glotblastn 2499 LNU218 cassava|09v1|DB926789 4217 627 80.57 glotblastn 2500 LNU218 poplar|10v1|CV236445 4218 627 80.3 globlastp 2501 LNU218 poplar|gb170|CV236445 4218 627 80.3 globlastp 2502 LNU218 cucumber|09v1|GD175338 4219 627 80.2 globlastp 2503 LNU219 arabidopsis_lyrata|09v1|BQ834518 4220 628 99 globlastp 2504 LNU219 aquilegia|10v1|DR932989 4221 628 95.9 globlastp 2505 LNU219 canola|10v1|CD815027 4222 628 94.6 globlastp 2506 LNU219 canola|gb161|CD815027 4222 628 94.6 globlastp 2507 LNU219 radish|gb164|EW714771 4223 628 94.4 globlastp 2508 LNU219 b_rapa|gb162|EX020921 4224 628 94.1 globlastp 2509 LNU219 canola|10v1|CD836405 4225 628 93.9 globlastp 2510 LNU219 canola|gb161|CD836405 4225 628 93.9 globlastp 2511 LNU219 radish|gb164|EV539520 4226 628 92.6 globlastp 2512 LNU219 cleome_gynandra|10v1|SRR015532S0004520 4227 628 88.3 globlastp 2513 LNU219 cleome_spinosa|10v1|GR935537 4228 628 85.9 globlastp 2514 LNU219 b_rapa|gb162|BG544276 4229 628 84.7 globlastp 2515 LNU219 b_oleracea|gb161|AM385469 4230 628 84.4 globlastp 2516 LNU219 canola|gb161|CD818834 4231 628 84.4 globlastp 2517 LNU219 canola|gb161|T18344 4230 628 84.4 globlastp 2518 LNU219 canola|10v1|CD818834 4231 628 84.4 globlastp 2519 LNU219 radish|gb164|EV527315 4232 628 83.9 globlastp 2520 LNU219 arabidopsis_lyrata|09v1|JGIAL028336 4233 628 83.6 globlastp 2521 LNU219 arabidopsis|gb165|AT5G45280 4234 628 82.6 globlastp 2522 LNU222 brachypodium|09v1|DV476280 4235 630 91.4 globlastp 2522 LNU222_H6 brachypodium|09v1|DV476280 4235 680 91.4 globlastp 2523 LNU222 brachypodium|gb169|BE400657 4235 630 91.4 globlastp 2523 LNU222_H6 brachypodium|gb169|BE400657 4235 680 91.4 globlastp 2524 LNU222 rice|gb170|OS06G47890 4236 630 89.7 globlastp 2524 LNU222_H6 rice|gb170|OS06G47890 4236 680 94 globlastp 2525 LNU222 switchgrass|gb167|DN143448 4237 630 89.2 globlastp 2525 LNU222_H6 switchgrass|gb167|DN143448 4237 680 95.7 globlastp 2526 LNU222 sorghum|09v1|SB10G028340 680 630 88 globlastp 2527 LNU222 maize|gb170|AI734407 4238 630 87.3 globlastp 2527 LNU222_H6 maize|gb170|AI734407 4238 680 90.3 globlastp 2528 LNU222 maize|gb170|AI820142 4239 630 83.9 glotblastn 2528 LNU222_H6 maize|gb170|AI820142 4239 680 86.53 glotblastn 2529 LNU222 rice|gb170|OS02G05700 4240 630 80.16 glotblastn 2529 LNU222_H6 rice|gb170|OS02G05700 4240 680 80.2 globlastp 2530 LNU222 brachypodium|09v1|GT771721 4241 630 80.1 glotblastn 2530 LNU222_H6 brachypodium|09v1|GT771721 4241 680 80.8 globlastp 2531 LNU222 brachypodium|gb169|BE406203 4241 630 80.1 glotblastn 2531 LNU222_H6 brachypodium|gb169|BE406203 4241 680 80.8 globlastp 2532 LNU223 pseudoroegneria|gb167|FF350748 4242 631 87.3 globlastp 2533 LNU223 wheat|gb164|BF474058 4242 631 87.3 globlastp 2534 LNU223 maize|gb170|AI461537 4243 631 87.2 globlastp 2535 LNU223 oat|10v1|CN821280 4244 631 86.9 globlastp 2536 LNU223 sorghum|09v1|SB03G026180 4245 631 86.7 globlastp 2537 LNU223 sorghum|gb161.crp|Y14675 4245 631 86.7 globlastp 2538 LNU223 brachypodium|09v1|DV475278 4246 631 86.6 globlastp 2539 LNU223 brachypodium|gb169|BF474058 4246 631 86.6 globlastp 2540 LNU223 switchgrass|gb167|FL697289 4247 631 86.6 globlastp 2541 LNU223 barley|gb157SOLEXA|AL500275 4248 631 86.2 globlastp 2542 LNU223 leymus|gb166|EG378630 4249 631 86 globlastp 2543 LNU223 maize|gb170|AI740070 4250 631 85.6 globlastp 2544 LNU224 pseudoroegneria|gb167|FF346115 4251 632 97.1 globlastp 2545 LNU224 leymus|gb166|EG379498 4252 632 96.4 globlastp 2546 LNU224 wheat|gb164|BQ789174 4253 632 96.4 globlastp 2547 LNU224 wheat|gb164|BE401267 4254 632 95 globlastp 2548 LNU224 oat|10v1|GR322386 4255 632 88.7 globlastp 2549 LNU228 wheat|gb164|BE406956 4256 634 89.89 glotblastn 2550 LNU229 potato|10v1|BE922224 4257 635 94.6 globlastp 2551 LNU229 solanum_phureja|09v1|SPHAI484048 4258 635 94.4 globlastp 2552 LNU230 brachypodium|09v1|TMPLOS12G40300T1 636 636 100 globlastp 2553 LNU234 arabidopsis_lyrata|09v1|JGIAL002366 4259 638 94.4 globlastp 2554 LNU239 oat|10v1|GO581462 4260 641 94.8 globlastp 2555 LNU239 oat|10v1|GO587061 4261 641 94.8 globlastp 2556 LNU239 oat|10v1|GO587140 4260 641 94.8 globlastp 2557 LNU239 oat|10v1|GR361871 4260 641 94.8 globlastp 2558 LNU239 sorghum|09v1|SB10G001510 4262 641 94.8 globlastp 2559 LNU239 sorghum|gb161.crp|AW330931 4262 641 94.8 globlastp 2560 LNU239 switchgrass|gb167|FE639067 4263 641 94.8 globlastp 2561 LNU239 millet|09v1|EVO454PM053563 4264 641 93.1 glotblastn 2562 LNU239 oat|10v1|GR361767 4265 641 93.1 globlastp 2563 LNU239 sugarcane|10v1|BQ533648 4266 641 93.1 globlastp 2564 LNU239 sugarcane|10v1|CA103102 4266 641 93.1 globlastp 2565 LNU239 sugarcane|gb157.3|BQ533648 4266 641 93.1 globlastp 2566 LNU239 oat|10v1|GO581699 4267 641 91.4 globlastp 2567 LNU239 sorghum|09v1|SB10G002810 4268 641 91.4 globlastp 2568 LNU239 maize|gb170|AW330931 4269 641 91.4 globlastp 2569 LNU239 switchgrass|gb167|DN150836 4270 641 89.7 globlastp 2570 LNU239 wheat|gb164|BE413591 4271 641 89.66 glotblastn 2571 LNU239 wheat|gb164|BE443361 4272 641 89.66 glotblastn 2572 LNU239 wheat|gb164|CA613749 4273 641 89.66 glotblastn 2573 LNU239 rye|gb164|BE495091 4274 641 87.93 glotblastn 2574 LNU239 barley|gb157.3|AL501772 4275 641 87.9 globlastp 2575 LNU239 barley|gb157SOLEXA|AL501772 4275 641 87.9 globlastp 2576 LNU239 brachypodium|09v1|DV469471 4276 641 87.9 globlastp 2577 LNU239 brachypodium|gb169|BE413591 4276 641 87.9 globlastp 2578 LNU239 pseudoroegneria|gb167|FF348954 4277 641 87.9 globlastp 2579 LNU239 leymus|gb166|CD808544 4278 641 86.2 globlastp 2580 LNU239 maize|gb170|CD980142 4279 641 84.7 globlastp 2581 LNU239 banana|gb167|FL649074 4280 641 84.48 glotblastn 2582 LNU239 ginger|gb164|DY381315 4281 641 82.76 glotblastn 2583 LNU239 rice|gb170|OS06G03514 4282 641 81 globlastp 2584 LNU242 b_rapa|gb162|EX031422 4283 644 92.45 glotblastn 2585 LNU242 canola|10v1|DY002989 4284 644 88.68 glotblastn 2586 LNU242 radish|gb164|EV566917 4285 644 84.51 glotblastn 2587 LNU243 wheat|gb164|BE414904 4286 645 92.86 glotblastn 2588 LNU245 potato|gb157.2|CK262157 4287 647 93.7 globlastp 2589 LNU245 eggplant|10v1|FS013675 4288 647 89 globlastp 2590 LNU245 potato|gb157.2|BG590426 4289 647 88.3 globlastp 2591 LNU245 solanum_phureja|09v1|SPHAI486625 4290 647 88 globlastp 2592 LNU245 potato|10v1|BG590608 4291 647 81.3 globlastp 2593 LNU246 solanum_phureja|09v1|SPHAI896232 4292 648 97.1 globlastp 2594 LNU246 potato|10v1|BG599206 4293 648 96.8 globlastp 2595 LNU246 potato|gb157.2|BG599206 4293 648 96.8 globlastp 2596 LNU247 arabidopsis_lyrata|09v1|JGIAL021212 4294 649 93.3 globlastp 2597 LNU247 canola|10v1|CN827557 4295 649 87.6 globlastp 2598 LNU247 canola|gb161|CD826643 4296 649 86.83 glotblastn 2599 LNU249 arabidopsis_lyrata|09v1|JGIAL020153 4297 650 96.6 globlastp 2600 LNU251 arabidopsis_lyrata|09v1|JGIAL023392 4298 652 97 globlastp 2601 LNU253 bean|gb167|CB540282 4299 653 92.12 glotblastn 2602 LNU253 cowpea|gb166|FF387997 4300 653 89.16 glotblastn 2603 LNU253 peanut|gb167|EG029988 4301 653 81.37 glotblastn 2604 LNU253 peanut|gb171|EG029988 4301 653 81.37 glotblastn 2605 LNU253 soybean|gb168|BE657859 4302 653 81.3 globlastp 2606 LNU254 arabidopsis_lyrata|09v1|JGIAL004106 4303 654 99.8 globlastp 2607 LNU254 radish|gb164|EV526765 4304 654 97.3 globlastp 2608 LNU254 canola|10v1|CD833572 4305 654 95.8 globlastp 2609 LNU254 radish|gb164|EV526356 4306 654 95.4 globlastp 2610 LNU254 canola|gb161|CD833572 4307 654 93 globlastp 2611 LNU254 cotton|gb164|CO095176 4308 654 90.94 glotblastn 2612 LNU254 cassava|09v1|JGICASSAVA12947VALIDM1 4309 654 90.4 globlastp 2613 LNU254 cucumber|09v1|AM720434 4310 654 90.4 globlastp 2614 LNU254 tomato|09v1|BQ119293 4311 654 90.3 globlastp 2615 LNU254 poplar|10v1|BI131005 4312 654 90.2 globlastp 2616 LNU254 poplar|gb170|BI131005 4312 654 90.2 globlastp 2617 LNU254 solanum_phureja|09v1|SPHBQ119293 4313 654 89.9 globlastp 2618 LNU254 castorbean|09v1|XM002510240 4314 654 89.8 globlastp 2619 LNU254 castorbean|gb160|MDL30170M013940 4314 654 89.8 globlastp 2620 LNU254 soybean|gb168|AW693383 4315 654 89.8 globlastp 2621 LNU254 chestnut|gb170|SRR006295S0002298 4316 654 89.5 globlastp 2622 LNU254 cassava|09v1|JGICASSAVA24790VALIDM1 4317 654 89.1 globlastp 2623 LNU254 soybean|gb168|BE320506 4318 654 89 globlastp 2624 LNU254 medicago|09v1|AL365842 4319 654 88.9 globlastp 2625 LNU254 potato|10v1|BQ119293 4320 654 87.5 globlastp 2626 LNU254 potato|gb157.2|BQ119293 4320 654 87.5 globlastp 2627 LNU254 aquilegia|10v1|DR914712 4321 654 86.4 globlastp 2628 LNU254 monkeyflower|10v1|GO954748 4322 654 85.5 globlastp 2629 LNU255 arabidopsis_lyrata|09v1|JGIAL015618 4323 655 87.3 globlastp 2630 LNU256 arabidopsis|gb165|AT2G43910 4324 656 83.3 globlastp 2631 LNU256 canola|10v1|EG020127 4325 656 81.9 globlastp 2632 LNU256 b_rapa|gb162|CA992319 4326 656 81.5 globlastp 2633 LNU256 b_rapa|gb162|L46502 4327 656 80.6 globlastp 2634 LNU256 b_oleracea|gb161|AF387791 4328 656 80.2 globlastp 2635 LNU256 canola|10v1|CD812772 4329 656 80.2 globlastp 2636 LNU256 canola|gb161|CD812772 4329 656 80.2 globlastp 2637 LNU256 radish|gb164|EV524444 4330 656 80.2 globlastp 2638 LNU257 arabidopsis_lyrata|09v1|JGIAL009641 4331 657 98.2 globlastp 2639 LNU257 radish|gb164|EV543963 4332 657 94.3 globlastp 2640 LNU257 thellungiella|gb167|BY830471 4333 657 94 globlastp 2641 LNU258 arabidopsis_lyrata|09v1|JGIAL024223 4334 658 90.65 glotblastn 2642 LNU260 thellungiella|gb167|DN774718 4335 659 84.9 globlastp 2643 LNU260 b_juncea|gb164|EVGN00742808281526 4336 659 82.8 globlastp 2644 LNU260 radish|gb164|EV536406 4337 659 80.8 globlastp 2645 LNU260 b_oleracea|gb161|DY015251 4338 659 80.51 glotblastn 2646 LNU260 radish|gb164|EV566818 4339 659 80.43 glotblastn 2647 LNU260 b_rapa|gb162|EX108082 4340 659 80.3 globlastp 2648 LNU260 b_rapa|gb162|ES932807 4341 659 80.08 glotblastn 2649 LNU260 canola|10v1|CX194829 4341 659 80.08 glotblastn 2650 LNU260 canola|gb161|CX194829 4341 659 80.08 glotblastn 2651 LNU260 radish|gb164|EV538732 4342 659 80 globlastp 2652 LNU261 arabidopsis_lyrata|09v1|JGIAL029133 4343 660 95.2 globlastp 2653 LNU261 radish|gb164|EV565501 4344 660 82.9 globlastp 2654 LNU262 arabidopsis_lyrata|09v1|JGIAL029381 4345 661 95.2 globlastp 2655 LNU263 wheat|gb164|BE403303 4346 662 92.6 globlastp 2656 LNU263 wheat|gb164|BE405309 4347 662 92.6 globlastp 2657 LNU263 barley|gb157SOLEXA|BE412891 4348 662 91.2 globlastp 2658 LNU263 leymus|gb166|EG394979 4349 662 84.5 glotblastn 2659 LNU263 brachypodium|09v1|DV474340 4350 662 83.9 globlastp 2660 LNU263 brachypodium|gb169|BE445700 4350 662 83.9 globlastp 2661 LNU263 brachypodium|09v1|DV473838 4351 662 82.9 globlastp 2662 LNU263 brachypodium|gb169|DV473838 4351 662 82.9 globlastp 2663 LNU263 sorghum|09v1|SB02G040500 4352 662 80.4 globlastp 2664 LNU263 sorghum|gb161.crp|BM382553 4352 662 80.4 globlastp 2665 LNU263 sorghum|09v1|SB02G040510 4353 662 80.2 globlastp 2666 LNU263 sorghum|gb161.crp|BM661046 4353 662 80.2 globlastp 2667 LNU265 sorghum|09v1|SB09G000890 4354 663 92 globlastp 2668 LNU265 sorghum|gb161.crp|BE597117 4355 663 86.3 globlastp 2669 LNU266 sorghum|09v1|SB03G002900 4356 664 93.6 globlastp 2670 LNU266 sorghum|gb161.crp|AI987574 4357 664 87.1 globlastp 2671 LNU267 maize|gb170|LLDV514913 4358 665 85.7 globlastp 2672 LNU267 maize|gb170|AI637120 4359 665 84 globlastp 2673 LNU267 sugarcane|10v1|BQ535909 4360 665 82.6 globlastp 2674 LNU267 sorghum|09v1|SB04G022740 4361 665 82.2 globlastp 2675 LNU267 sorghum|gb161.crp|AW283751 4361 665 82.2 globlastp 2676 LNU267 switchgrass|gb167|FE640888 4362 665 82 globlastp 2677 LNU267 sugarcane|gb157.3|BQ535909 4363 665 81.1 globlastp 2678 LNU267 switchgrass|gb167|FE621258 4364 665 81.1 globlastp 2679 LNU268 sorghum|09v1|SB03G002890 4365 666 94.8 globlastp 2680 LNU268 sorghum|gb161.crp|BF656912 4365 666 94.8 globlastp 2681 LNU268 sugarcane|gb157.3|CA082317 4366 666 93.8 globlastp 2682 LNU268 maize|gb170|LLEE026298 4367 666 92.2 globlastp 2683 LNU268 switchgrass|gb167|DN141482 4368 666 91.7 globlastp 2684 LNU268 sugarcane|10v1|CA219295 4369 666 86.53 glotblastn 2685 LNU268 barley|gb157SOLEXA|BE060428 4370 666 85.5 globlastp 2686 LNU268 brachypodium|09v1|GT836297 4371 666 84.5 globlastp 2687 LNU271 brachypodium|09v1|GT783626 4372 667 90.2 globlastp 2688 LNU271 brachypodium|gb169|BF483222 4372 667 90.2 globlastp 2689 LNU271 wheat|gb164|BF483222 4373 667 90.2 globlastp 2690 LNU271 wheat|gb164|CA700889 4373 667 90.2 globlastp 2691 LNU271 sorghum|09v1|SB01G043280 4374 667 89 globlastp 2692 LNU271 sorghum|gb161.crp|CD210322 4374 667 89 globlastp 2693 LNU271 oat|10v1|GO592793 4375 667 87.9 globlastp 2694 LNU271 switchgrass|gb167|DN144438 4376 667 87.3 globlastp 2695 LNU271 maize|gb170|CD944785 4377 667 86.1 globlastp 2696 LNU271 maize|gb170|H35893 4378 667 85 globlastp 2697 LNU271 millet|09v1|EVO454PM060798 4379 667 84.1 globlastp 2698 LNU271 fescue|gb161|DT710736 4380 667 83.8 globlastp 2699 LNU274 rice|gb170|OS05G01750 4381 668 93 globlastp 2700 LNU275 brachypodium|09v1|SRR031797S0128470 4382 669 80.33 glotblastn 2701 LNU275 sorghum|09v1|SB02G030360 4383 669 80.3 globlastp 2702 LNU275 maize|gb170|DN213402 4384 669 80.1 globlastp 2703 LNU278 switchgrass|gb167|FL852997 4385 672 93 globlastp 2704 LNU278 millet|09v1|EVO454PM020322 4386 672 90.6 globlastp 2705 LNU278 brachypodium|09v1|GT841667 4387 672 88.1 globlastp 2706 LNU278 brachypodium|gb169|BG343026 4387 672 88.1 globlastp 2707 LNU278 leymus|gb166|EG395159 4388 672 87.9 globlastp 2708 LNU278 oat|10v1|GR322586 4389 672 87.4 globlastp 2709 LNU278 maize|gb170|DR964461 4390 672 86.4 globlastp 2710 LNU278 maize|gb170|DN217333 4391 672 83.1 globlastp 2711 LNU278 rice|gb170|OS05G03530 4392 672 83.05 glotblastn 2712 LNU278 sugarcane|gb157.3|CA139449 4393 672 81.5 globlastp 2713 LNU279 maize|gb170|AW126569 4394 673 92 globlastp 2714 LNU279 maize|gb170|DR823071 4395 673 91.7 globlastp 2715 LNU279 maize|gb170|CF014369 4396 673 87.1 globlastp 2716 LNU279 maize|gb170|CD961214 4397 673 84.8 globlastp 2717 LNU279 sorghum|09v1|SB02G037590 4398 673 84.7 globlastp 2718 LNU280 switchgrass|gb167|FL809443 4399 674 90.5 globlastp 2719 LNU280 maize|gb170|BM498380 4400 674 88.5 globlastp 2720 LNU280 rice|gb170|OS11G23790 4401 674 83.8 globlastp 2721 LNU280 brachypodium|09v1|DV474046 4402 674 83 globlastp 2722 LNU280 brachypodium|gb169|BF482671 4403 674 82.49 glotblastn 2723 LNU280 wheat|gb164|BF293467 4404 674 82.28 glotblastn 2724 LNU282 soybean|gb168|BQ630236 4405 675 96.9 globlastp 2725 LNU282 medicago|09v1|AW686001 4406 675 86.4 globlastp 2726 LNU282 lotus|09v1|AI967570 4407 675 81.5 globlastp 2727 LNU284 soybean|gb168|CF807230 4408 676 93 globlastp 2728 LNU284 soybean|gb168|BQ080894 4409 676 92.8 globlastp 2729 LNU284 soybean|gb168|AW351157 4410 676 82.7 globlastp 2730 LNU288 solanum_phureja|09v1|SPHBG134658 4411 678 97.7 globlastp 2731 LNU288 potato|10v1|BE920963 4412 678 96.7 globlastp 2732 LNU288 potato|gb157.2|BE920963 4412 678 96.7 globlastp 2733 LNU288 tobacco|gb162|AB014483 4413 678 85.8 globlastp 2734 LNU289 solanum_phureja|09v1|SPHBG123295 4414 679 97.2 globlastp 2735 LNU289 potato|gb157.2|BG592935 4415 679 96.5 globlastp 2736 LNU289 potato|10v1|BG592935 4416 679 95.1 globlastp 2737 LNU289 eggplant|10v1|FS024715 4417 679 93.6 globlastp 2738 LNU289 pepper|gb171|CK901930 4418 679 81.27 glotblastn 2739 LNU222_H6 sorghum|09v1|SB04G003660 4419 680 81.3 globlastp 2740 LNU222_H6 maize|gb170|AW928070 4420 680 81 globlastp 2741 LNU29 potato|10v1|BM405532 3260 681 89.42 glotblastn 2742 LNU35 rice|gb170|OS07G13590 4421 682 89.97 glotblastn 2743 LNU35 sorghum|09v1|SB02G007060 4422 682 89.62 glotblastn 2744 LNU35 sorghum|gb161.crp|AW067593 4422 682 89.62 glotblastn 2745 LNU35 maize|gb170|AI601000 4423 682 89.27 glotblastn 2746 LNU35 barley|gb157.3|AV833599 4424 682 89.1 globlastp 2747 LNU35 barley|gb157SOLEXA|AV833599 4425 682 89.1 globlastp 2748 LNU35 brachypodium|gb169|BE442655 4426 682 86.2 globlastp 2749 LNU55 soybean|gb168|SB2GWP093054 4427 684 88.1 globlastp 2750 LNU60 barley|gb157SOLEXA|BG368863 4428 686 92.82 glotblastn 2751 LNU60 barley|gb157.3|BG368863 4428 686 92.53 glotblastn 2752 LNU60 pseudoroegneria|gb167|FF360223 4429 686 81.6 globlastp 2753 LNU60 switchgrass|gb167|FL699261 4430 686 80.52 glotblastn 2754 LNU83 cowpea|gb166|FF386177 4431 687 89.08 glotblastn 2755 LNU83 peanut|gb171|EE124103 4432 687 80.28 glotblastn 2756 LNU89 pseudoroegneria|gb167|FF341285 4433 688 95.76 glotblastn 2757 LNU89 maize|gb170|AA979933 4434 688 80.08 glotblastn 2758 LNU115 rice|gb170|OS03G21740 4435 693 83.6 globlastp 2759 LNU115 wheat|gb164|BE498586 4436 693 80.1 glotblastn 2760 LNU170 arabidopsis_lyrata|09v1|TMPLAT5G40060T1 4437 697 100 glotblastn 2761 LNU192 sugarcane|gb157.3|BQ533786 4438 698 93.97 glotblastn 2762 LNU192 switchgrass|gb167|FL700814 4439 698 91.11 glotblastn 2763 LNU192 monkeyflower|10v1|GR013631 4440 698 86.67 glotblastn 2764 LNU192 poplar|gb170|BI138135 4441 698 82.54 glotblastn 2765 LNU192 poplar|10v1|BI138135 4442 698 82.22 glotblastn 2766 LNU192 poplar|10v1|XM002307099 4443 698 81.88 glotblastn 2767 LNU192 poplar|gb170|XM002307099 4444 698 81.88 glotblastn 2768 LNU192 cucumber|09v1|CV001584 4445 698 81.59 glotblastn 2769 LNU192 soybean|gb168|BQ252456 4446 698 81.27 glotblastn 2770 LNU192 castorbean|09v1|XM002532133 4447 698 80.95 glotblastn 2771 LNU192 medicago|09v1|AW689616 4448 698 80.95 glotblastn 2772 LNU192 soybean|gb168|BM523433 4449 698 80.95 glotblastn 2773 LNU229 potato|gb157.2|BE922224 4450 701 93.8 globlastp 2774 LNU242 arabidopsis_lyrata|09v1|JGIAL023703 4451 703 88.6 globlastp 2775 LNU265 switchgrass|gb167|FE626072 4452 705 86.1 globlastp 2776 LNU4 rye|gb164|BE494134 4453 708 95.5 globlastp 2777 LNU4 wheat|gb164|BE430340 4454 708 94.2 globlastp 2778 LNU4 wheat|gb164|BQ743944 4455 708 93.5 globlastp 2779 LNU4 wheat|gb164|CD935835 4456 708 92.9 globlastp 2780 LNU4 brachypodium|09v1|DV474688 4457 708 86.4 globlastp 2781 LNU4 brachypodium|gb169|BE494134 4457 708 86.4 globlastp 2782 LNU4 oat|10v1|GR330356 4458 708 84.4 globlastp 2783 LNU4 barley|gb157.3|BI955043 4459 708 84.1 globlastp 2784 LNU4 barley|gb157SOLEXA|BI955043 4459 708 84.1 globlastp 2785 LNU4 barley|gb157SOLEXA|BE519514 4460 708 81.1 globlastp 2786 LNU4 oat|10v1|GR364394 4461 708 80.5 globlastp 2787 LNU4 wheat|gb164|CK214316 4462 708 80.4 globlastp 2788 LNU28 oat|10v1|GR315782 4463 712 90.9 globlastp 2789 LNU28 sorghum|09v1|SB03G008060 4464 712 83.7 globlastp 2790 LNU28 sorghum|gb161.crp|AW283962 4464 712 83.7 globlastp 2791 LNU28 sugarcane|10v1|CA109293 4465 712 82 globlastp 2792 LNU28 rice|gb170|OS01G02870 4466 712 81.7 globlastp 2793 LNU28 sugarcane|gb157.3|CA109293 4467 712 81.5 globlastp 2794 LNU28 switchgrass|gb167|FE643547 4468 712 80.2 globlastp 2795 LNU35 brachypodium|09v1|DV488691 4469 714 85.8 globlastp 2796 LNU36 soybean|gb168|BG839931 4470 715 80.4 globlastp 2797 LNU54 soybean|gb168|BG839336 4471 717 94.9 globlastp 2798 LNU54 cowpea|gb166|FC457406 4472 717 85.5 globlastp 2799 LNU54 bean|gb167|CA905321 4473 717 85 globlastp 2800 LNU58 wheat|gb164|BE430622 4474 719 88.4 globlastp 2801 LNU58 wheat|gb164|CA622084 4475 719 82.8 globlastp 2802 LNU58 wheat|gb164|BF484060 4476 719 80.4 globlastp 2803 LNU64 wheat|gb164|AJ603788 4477 721 92.2 globlastp 2803 LNU98 wheat|gb164|AJ603788 4477 734 80.2 globlastp 2804 LNU64 millet|09v1|CD725273 4478 721 83.5 globlastp 2804 LNU98 millet|09v1|CD725273 4478 734 82.2 globlastp 2805 LNU64 wheat|gb164|BE591591 4479 721 82.6 globlastp 2805 LNU98 wheat|gb164|BE591591 4479 734 80.23 glotblastn 2806 LNU70 wheat|gb164|BE492123 4480 724 92.41 glotblastn 2807 LNU70 barley|gb157SOLEXA|AL506812 4481 724 92.1 globlastp 2808 LNU70 brachypodium|09v1|DV469959 4482 724 90.9 globlastp 2809 LNU70 sugarcane|10v1|BQ533718 4483 724 90.9 globlastp 2810 LNU70 maize|gb170|AA051893 4484 724 90.5 globlastp 2811 LNU70 switchgrass|gb167|FE616904 4485 724 90.3 globlastp 2812 LNU70 sorghum|09v1|SB02G000720 4486 724 90.2 globlastp 2813 LNU70 maize|gb170|LLBM501434 4487 724 89.9 globlastp 2814 LNU70 switchgrass|gb167|FE597592 4488 724 89.7 globlastp 2815 LNU70 rice|gb170|OS07G01020 4489 724 89.6 globlastp 2816 LNU70 rice|gb170|OS10G01080 4490 724 89.2 globlastp 2817 LNU70 oat|10v1|GR350932 4491 724 87.7 glotblastn 2818 LNU70 ginger|gb164|DY345087 4492 724 87.5 globlastp 2819 LNU70 ginger|gb164|DY345406 4493 724 87.5 globlastp 2820 LNU70 leymus|gb166|EG378516 4494 724 87.2 globlastp 2821 LNU70 brachypodium|09v1|SRR031795S0034512 4495 724 86.9 globlastp 2822 LNU70 barley|gb157SOLEXA|BE421769 4496 724 86.7 globlastp 2823 LNU70 antirrhinum|gb166|AJ794293 4497 724 86.2 globlastp 2824 LNU70 aquilegia|10v1|DR915720 4498 724 86.2 globlastp 2825 LNU70 orobanche|10v1|SRR023189S0008709 4499 724 86.2 globlastp 2826 LNU70 cleome_gynandra|10v1|SRR015532S0033509 4500 724 85.9 globlastp 2827 LNU70 wheat|gb164|BE216934 4501 724 85.8 globlastp 2828 LNU70 cotton|gb164|AI731099 4502 724 85.6 globlastp 2829 LNU70 cotton|gb164|AI727639 4503 724 85.3 globlastp 2830 LNU70 cassava|09v1|CK646456 4504 724 84.9 globlastp 2831 LNU70 cleome_gynandra|10v1|SRR015532S0002004 4505 724 84.9 globlastp 2832 LNU70 grape|gb160|BM436391 4506 724 84.9 globlastp 2833 LNU70 oat|10v1|GR314124 4507 724 84.9 globlastp 2834 LNU70 soybean|gb168|AL368316 4508 724 84.9 globlastp 2835 LNU70 artemisia|gb164|EY100674 4509 724 84.6 globlastp 2836 LNU70 monkeyflower|10v1|DV211139 4510 724 84.6 globlastp 2837 LNU70 poplar|10v1|BU821620 4511 724 84.6 globlastp 2838 LNU70 soybean|gb168|BG583573 4512 724 84.6 globlastp 2839 LNU70 cleome_gynandra|10v1|SRR015532S0001986 4513 724 84.4 globlastp 2840 LNU70 apple|gb171|CN581367 4514 724 84.3 globlastp 2841 LNU70 aquilegia|10v1|DR926939 4515 724 84.3 globlastp 2842 LNU70 bean|gb167|AY007525 4516 724 84.3 globlastp 2843 LNU70 cichorium|gb171|EH673869 4517 724 84.3 globlastp 2844 LNU70 citrus|gb166|CB291221 4518 724 84.3 globlastp 2845 LNU70 lettuce|10v1|DW065212 4517 724 84.3 globlastp 2846 LNU70 lettuce|10v1|DW074895 4517 724 84.3 globlastp 2847 LNU70 b_rapa|gb162|CV650466 4519 724 84 globlastp 2848 LNU70 canola|10v1|BQ704215 4519 724 84 globlastp 2849 LNU70 cowpea|gb166|FC459209 4520 724 84 globlastp 2850 LNU70 cucumber|09v1|BI740201 4521 724 84 globlastp 2851 LNU70 ipomoea_nil|10v1|BJ563728 4522 724 84 globlastp 2852 LNU70 pepper|gb171|BM059644 4523 724 84 globlastp 2853 LNU70 poplar|10v1|BI071183 4524 724 84 globlastp 2854 LNU70 potato|10v1|BG350133 4525 724 84 globlastp 2855 LNU70 solanum_phureja|09v1|SPHBG127432 4525 724 84 globlastp 2856 LNU70 sunflower|gb162|DY910980 4526 724 84 globlastp 2857 LNU70 thellungiella|gb167|DN773941 4527 724 84 globlastp 2858 LNU70 b_rapa|gb162|CV544377 4528 724 83.7 globlastp 2859 LNU70 canola|10v1|CX193292 4528 724 83.7 globlastp 2860 LNU70 canola|10v1|EE413831 4529 724 83.7 globlastp 2861 LNU70 canola|10v1|EE470024 4530 724 83.7 globlastp 2862 LNU70 chestnut|gb170|SRR006295S0008684 4531 724 83.7 globlastp 2863 LNU70 eggplant|10v1|FS022577 4532 724 83.7 globlastp 2864 LNU70 nicotiana_benthamiana|gb162| 4533 724 83.7 globlastp CN744951 2865 LNU70 tobacco|gb162|GFXAY532656X1 4533 724 83.7 globlastp 2866 LNU70 tomato|09v1|BG127432 4534 724 83.7 globlastp 2867 LNU70 kiwi|gb166|FG409049 4535 724 83.4 globlastp 2868 LNU70 strawberry|gb164|CO379446 4536 724 83.4 globlastp 2869 LNU70 arabidopsis_lyrata|09v1|BQ834310 4537 724 83.3 globlastp 2870 LNU70 arabidopsis|gb165|AT5G01410 4537 724 83.3 globlastp 2871 LNU70 canola|10v1|CB686329 4538 724 83.3 globlastp 2872 LNU70 cassava|09v1|CK643506 4539 724 83.1 globlastp 2873 LNU70 canola|10v1|CB686238 4540 724 83 globlastp 2874 LNU70 clover|gb162|BB936964 4541 724 82.7 globlastp 2875 LNU70 lotus|09v1|DQ139264 4542 724 82.7 globlastp 2876 LNU70 citrus|gb166|CB292808 4543 724 82.4 globlastp 2877 LNU70 lettuce|10v1|DW090121 4544 724 82.4 globlastp 2878 LNU70 papaya|gb165|EX254443 4545 724 82.4 globlastp 2879 LNU70 strawberry|gb164|EX658116 4546 724 82.2 globlastp 2880 LNU70 castorbean|09v1|EG661356 4547 724 82.11 glotblastn 2881 LNU70 cotton|gb164|DT555568 4548 724 82.1 globlastp 2882 LNU70 cryptomeria|gb166|BP175070 4549 724 82.1 globlastp 2883 LNU70 spruce|gb162|CO222779 4550 724 82.1 globlastp 2884 LNU70 spruce|gb162|CO478481 4551 724 82.1 globlastp 2885 LNU70 cynara|gb167|GE587800 4552 724 82.05 glotblastn 2886 LNU70 pine|10v1|CO170442 4553 724 81.7 globlastp 2887 LNU70 arabidopsis_lyrata|09v1|JGIAL015042 4554 724 81.4 globlastp 2888 LNU70 arabidopsis|gb165|AT2G38230 4555 724 81.4 globlastp 2889 LNU70 fern|gb171|BP912037 4556 724 81.4 globlastp 2890 LNU70 pine|10v1|CF470198 4557 724 81.4 globlastp 2891 LNU70 radish|gb164|EY902227 4558 724 81.4 globlastp 2892 LNU70 medicago|09v1|AW695944 4559 724 81.3 globlastp 2893 LNU70 b_oleracea|gb161|AM385028 4560 724 80.9 globlastp 2894 LNU70 cucumber|09v1|AM723122 4561 724 80.6 globlastp 2895 LNU70 spikemoss|gb165|FE429245 4562 724 80.13 glotblastn 2896 LNU70 spikemoss|gb165|FE451328 4562 724 80.13 glotblastn 2897 LNU74 switchgrass|gb167|FE639952 4563 726 86.7 globlastp 2898 LNU74 millet|09v1|EVO454PM015812 4564 726 86.57 glotblastn 2899 LNU74 switchgrass|gb167|FE657764 4565 726 85.9 globlastp 2900 LNU74 rice|gb170|OS04G43540 4566 726 85.8 globlastp 2901 LNU74 brachypodium|09v1|DV476963 4567 726 85.2 globlastp 2902 LNU74 maize|gb170|AI621531 4568 726 85.2 globlastp 2903 LNU74 maize|gb170|LLBE128837 4568 726 85.2 globlastp 2904 LNU74 pseudoroegneria|gb167|FF342634 4569 726 85.2 globlastp 2905 LNU74 sorghum|09v1|SB06G022580 4570 726 85.2 globlastp 2906 LNU74 sorghum|gb161.crp|AI901612 4570 726 85.2 globlastp 2907 LNU74 sugarcane|10v1|CA073228 4568 726 85.2 globlastp 2908 LNU74 sugarcane|gb157.3|CA073228 4568 726 85.2 globlastp 2909 LNU74 oat|10v1|CN819453 4571 726 85.1 globlastp 2910 LNU74 brachypodium|09v1|DV479778 4572 726 85.1 globlastp 2911 LNU74 brachypodium|gb169|BE403473 4572 726 85.1 globlastp 2912 LNU74 rice|gb170|OS02G40880 4573 726 85.1 globlastp 2913 LNU74 sugarcane|gb157.3|CA084445 4574 726 85.1 globlastp 2914 LNU74 sugarcane|10v1|CA084445 4574 726 85.1 globlastp 2915 LNU74 wheat|gb164|BE429979 4575 726 84.4 globlastp 2916 LNU74 barley|gb157.3|BE421867 4576 726 84.3 globlastp 2917 LNU74 barley|gb157SOLEXA|BE421867 4576 726 84.3 globlastp 2918 LNU74 maize|gb170|LLDQ244985 4577 726 84.3 globlastp 2919 LNU74 sugarcane|gb157.3|CA119465 4578 726 84.3 globlastp 2920 LNU74 switchgrass|gb167|FE612757 4579 726 84.3 globlastp 2921 LNU74 switchgrass|gb167|FE644412 4579 726 84.3 globlastp 2922 LNU74 wheat|gb164|BE403473 4577 726 84.3 globlastp 2923 LNU74 wheat|gb164|TAU91834 4577 726 84.3 globlastp 2924 LNU74 oat|10v1|GO585574 4580 726 83.7 globlastp 2925 LNU74 fescue|gb161|DT690215 4581 726 83.7 globlastp 2926 LNU74 maize|gb170|LLDQ245227 4582 726 83.7 globlastp 2927 LNU74 wheat|gb164|BE400933 4582 726 83.7 globlastp 2928 LNU74 wheat|gb164|BE406339 4582 726 83.7 globlastp 2929 LNU74 eggplant|10v1|FS000049 4583 726 83.6 globlastp 2930 LNU74 millet|09v1|EVO454PM021136 4584 726 83.6 globlastp 2931 LNU74 sugarcane|10v1|CA073639 4585 726 83.6 globlastp 2932 LNU74 lovegrass|gb167|EH186458 4586 726 83.6 globlastp 2933 LNU74 maize|gb170|LLCF630355 4587 726 83.6 globlastp 2934 LNU74 maize|gb170|W21624 4587 726 83.6 globlastp 2935 LNU74 sorghum|09v1|SB02G031930 4588 726 83.6 globlastp 2936 LNU74 sorghum|gb161.crp|AW011692 4588 726 83.6 globlastp 2937 LNU74 sugarcane|gb157.3|CA073639 4589 726 83.6 globlastp 2938 LNU74 barley|gb157SOLEXA|AL500999 4590 726 83 globlastp 2939 LNU74 rye|gb164|BE587782 4591 726 82.84 glotblastn 2940 LNU74 eucalyptus|gb166|CT985211 4592 726 82.8 globlastp 2941 LNU74 maize|gb170|AI942046 4593 726 82.8 globlastp 2942 LNU74 maize|gb170|LLCF004305 4594 726 82.1 globlastp 2943 LNU74 brachypodium|gb169|BE400933 4595 726 81.4 globlastp 2944 LNU74 cotton|gb164|BM360100 4596 726 81.34 glotblastn 2945 LNU87 millet|09v1|EVO454PM017414 4597 731 91.5 globlastp 2946 LNU87 brachypodium|09v1|SRR031797S0046443 4598 731 84.46 glotblastn 2947 LNU87 brachypodium|gb169|BF145866 4599 731 82.4 glotblastn 2948 LNU87 rice|gb170|OS02G12900 4600 731 81.82 glotblastn 2949 LNU89 wheat|gb164|BE429720 4601 732 98.2 globlastp 2950 LNU89 barley|gb157SOLEXA|BE421794 4602 732 94.8 globlastp 2951 LNU89 oat|10v1|CN818133 4603 732 92.7 globlastp 2952 LNU89 brachypodium|09v1|DV473902 4604 732 91.1 globlastp 2953 LNU89 leymus|gb166|EG390106 4605 732 86.6 globlastp 2954 LNU89 switchgrass|gb167|FE650349 4606 732 80.9 globlastp 2955 LNU89 sorghum|09v1|SB01G028410 4607 732 80.1 globlastp 2956 LNU89 sorghum|gb161.crp|AA979933 4607 732 80.1 globlastp 2957 LNU98 sugarcane|10v1|CA151185 4608 734 92.84 glotblastn 2958 LNU98 sugarcane|gb157.3|CA151185 4609 734 91.69 glotblastn 2959 LNU128 radish|gb164|EV568872 4610 742 93.8 globlastp 2960 LNU128 canola|10v1|DY011559 4611 742 93.5 globlastp 2961 LNU128 canola|gb161|BQ704843 4612 742 93.2 globlastp 2962 LNU128 citrus|gb166|CX069720 4613 742 84.37 glotblastn 2963 LNU128 cotton|gb164|AJ513046 4614 742 84 globlastp 2964 LNU128 cacao|gb167|CU482048 4615 742 83.7 globlastp 2965 LNU128 grape|gb160|CB911162 4616 742 83.7 globlastp 2966 LNU128 potato|10v1|BG598087 4617 742 83.19 glotblastn 2967 LNU128 potato|gb157.2|BG598087 4618 742 83.19 glotblastn 2968 LNU128 solanum_phureja|09v1|SPHBG133047 4619 742 82.7 globlastp 2969 LNU128 tomato|09v1|BG133047 4620 742 82.7 globlastp 2970 LNU128 tomato|gb164|BG133047 4620 742 82.7 globlastp 2971 LNU128 eggplant|10v1|FS026981 4621 742 82.4 globlastp 2972 LNU128 cucumber|09v1|CSCRP021916 4622 742 82.3 globlastp 2973 LNU128 cassava|09v1|DV441652 4623 742 81.9 globlastp 2974 LNU128 kiwi|gb166|FG489702 4624 742 81.6 globlastp 2975 LNU128 rice|gb170|OS12G07720 4625 742 81.5 globlastp 2976 LNU128 castorbean|09v1|GE635249 4626 742 81 globlastp 2977 LNU128 castorbean|gb160|MDL29648M002000 4626 742 81 globlastp 2978 LNU128 sugarcane|10v1|CA074195 4627 742 80.9 globlastp 2979 LNU128 sugarcane|gb157.3|CA074195 4627 742 80.9 globlastp 2980 LNU128 switchgrass|gb167|FE607245 4628 742 80.9 globlastp 2981 LNU128 poplar|gb170|AI164310 4629 742 80.88 glotblastn 2982 LNU128 peanut|gb171|GO332421 4630 742 80.83 glotblastn 2983 LNU128 sorghum|09v1|SB08G004780 4631 742 80.6 globlastp 2984 LNU128 sorghum|gb161.crp|BM324980 4631 742 80.6 globlastp 2985 LNU128 sorghum|09v1|SB01G045530 4632 742 80.6 globlastp 2986 LNU128 sorghum|gb161.crp|CB334193 4632 742 80.6 globlastp 2987 LNU128 soybean|gb168|BF520452 4633 742 80.5 globlastp 2988 LNU128 apple|gb157.3|CN495076 4634 742 80.3 globlastp 2989 LNU128 apple|gb171|CN495076 4634 742 80.3 globlastp 2990 LNU128 aquilegia|10v1|DR941443 4635 742 80.24 glotblastn 2991 LNU128 monkeyflower|10v1|GR109554 4636 742 80.24 glotblastn 2992 LNU128 sunflower|gb162|DY947958 4637 742 80.24 glotblastn 2993 LNU128 poplar|10v1|AI164310 4638 742 80.2 globlastp 2994 LNU129 arabidopsis_lyrata|09v1|JGIAL004858 4639 743 89.6 globlastp 2995 LNU129 canola|10v1|CD827308 4640 743 81.2 globlastp 2996 LNU129 canola|gb161|CD827308 4640 743 81.2 globlastp 2997 LNU135 arabidopsis_lyrata|09v1|JGIAL023957 4641 747 96.6 globlastp 2998 LNU135 thellungiella|gb167|BM985897 4642 747 92.5 globlastp 2999 LNU135 b_oleracea|gb161|EH416218 4643 747 88.4 globlastp 3000 LNU135 canola|10v1|CD821934 4643 747 88.4 globlastp 3001 LNU135 b_rapa|gb162|CA991582 4644 747 88 globlastp 3002 LNU135 canola|10v1|CD820689 4645 747 88 globlastp 3003 LNU135 canola|gb161|CD820689 4645 747 88 globlastp 3004 LNU135 canola|10v1|CX189037 4646 747 87.3 globlastp 3005 LNU135 radish|gb164|EW735630 4647 747 86.9 globlastp 3006 LNU135 radish|gb164|EV567321 4648 747 86.5 globlastp 3007 LNU135 canola|gb161|CD821934 4649 747 84.6 globlastp 3008 LNU135 cleome_gynandra|10v1|SRR015532S0008526 4650 747 82.4 globlastp 3009 LNU140 arabidopsis_lyrata|09v1|JGIAL005684 4651 748 90 globlastp 3010 LNU140 cassava|09v1|DV446155 4652 748 81.8 globlastp 3011 LNU140 citrus|gb166|CB250310 4653 748 80.29 glotblastn 3012 LNU150 cotton|gb164|BE052334 4654 752 96.9 globlastp 3013 LNU150 cacao|gb167|CU477864 4655 752 88.9 globlastp 3014 LNU150 heritiera|10v1|SRR005795S0012955 4656 752 86.9 globlastp 3015 LNU150 tea|10v1|CV013763 4657 752 83.5 globlastp 3016 LNU150 poplar|10v1|AI162436 4658 752 81.4 globlastp 3017 LNU171 barley|gb157SOLEXA|BE412872 4659 757 96.6 globlastp 3018 LNU171 barley|gb157.3|BE412872 4660 757 95.9 globlastp 3019 LNU171 barley|gb157.3|BI777448 4661 757 91.8 globlastp 3020 LNU171 barley|gb157SOLEXA|BI777448 4661 757 91.8 globlastp 3021 LNU171 wheat|gb164|AL822126 4662 757 87.07 glotblastn 3022 LNU171 wheat|gb164|BE415359 4663 757 85.7 globlastp 3023 LNU171 wheat|gb164|BG607128 4664 757 83.9 globlastp 3024 LNU171 wheat|gb164|CA727731 4665 757 81 globlastp 3025 LNU172 wheat|gb164|CV774671 4666 758 84.5 globlastp 3026 LNU172 wheat|gb164|BQ807177 4667 758 81.8 globlastp 3027 LNU172 wheat|gb164|CA621288 4668 758 80.5 globlastp 3028 LNU179 arabidopsis_lyrata|09v1|JGIAL004871 4669 760 92.8 globlastp 3029 LNU212 arabidopsis_lyrata|09v1|JGIAL002964 4670 764 94.3 globlastp 3030 LNU212 radish|gb164|EV544090 4671 764 80.9 globlastp 3031 LNU212 canola|gb161|H74617 4672 764 80.8 globlastp 3032 LNU235 arabidopsis_lyrata|09v1|JGIAL003487 4673 770 93.92 glotblastn 3033 LNU235 radish|gb164|EV524630 4674 770 87.7 globlastp 3034 LNU235 thellungiella|gb167|BM985688 4675 770 87.42 glotblastn 3035 LNU235 b_rapa|gb162|L46407 4676 770 85.6 globlastp 3036 LNU250 arabidopsis_lyrata|09v1|JGIAL003223 4677 775 87 globlastp 3037 LNU253 lotus|gb157.2|BU494491 4678 777 84.39 glotblastn 3038 LNU253 lotus|09v1|LLBU494491 4679 777 83.4 globlastp 3039 LNU253 chickpea|09v2|DY475475 4680 777 80.39 glotblastn 3040 LNU256 arabidopsis_lyrata|09v1|JGIAL015756 4681 779 83.3 globlastp 3041 LNU260 arabidopsis_lyrata|09v1|JGIAL020384 4682 781 95.7 globlastp Table 2: Provided are the homologous polypeptides and polynucleotides of the genes identified in Table 1 and of their cloned genes, which can increase nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, abiotic stress tolerance and/or water use efficiency of a plant. Homology was calculated as % of identity over the aligned sequences. The query sequences were polypeptide sequences SEQ ID NOs: 468-706, and 707-784 and the subject sequences are polypeptide sequences or polynucleotide sequences which were dynamically translated in all six reading frames identified in the database based on greater than 80% identity to the query polypeptide sequences. “Polyp.” = polypeptide; “Polyn.”—Polynucleotide. Algor. = Algorithm. “globlastp”—global homology using blastp; “glotblastn”—global homology using tblastn. “Hom.”—homologous.

The output of the functional genomics approach described herein is a set of genes highly predicted to improve nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber length, fiber quality, abiotic stress tolerance and/or water use efficiency of a plant by increasing their expression.

Although each gene is predicted to have its own impact, modifying the mode of expression of more than one gene or gene product (RNA, polypeptide) is expected to provide an additive or synergistic effect on the desired trait (e.g., nitrogen use efficiency, fertilizer use efficiency, yield, growth rate, vigor, biomass, oil content, abiotic stress tolerance and/or water use efficiency of a plant). Altering the expression of each gene described here alone or of a set of genes together increases the overall yield and/or other agronomic important traits, hence expects to increase agricultural productivity.

Example 3 Production of Arabidopsis Transcriptom and High Throughput Correlation Analysis Using 44K Arabidopsis Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a Arabidopsis oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 44,000 Arabidopsis genes and transcripts. To define correlations between the levels of RNA expression with NUE, yield components or vigor related parameters various plant characteristics of 14 different Arabidopsis ecotypes were analyzed. Among them, ten ecotypes encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures Analyzed Arabidopsis tissues—Two tissues of plants [leaves and stems] growing at two different nitrogen fertilization levels (1.5 mM Nitrogen or 6 mM Nitrogen) were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized Table 3 below.

TABLE 3 Arabidopsis transcriptom experimental sets Expression Set Set ID Leaves at 1.5 mM Nitrogen fertilization A Leaves at 6 mM Nitrogen fertilization B Stems at 1.5 mM Nitrogen fertilization C Stem at 6 mM Nitrogen fertilization D Table 3.

Arabidopsis yield components and vigor related parameters under different nitrogen fertilization levels assessment—10 Arabidopsis accessions in 2 repetitive plots each containing 8 plants per plot were grown at greenhouse. The growing protocol used was as follows: surface sterilized seeds were sown in Eppendorf tubes containing 0.5×Murashige-Skoog basal salt medium and grown at 23° C. under 12-hour light and 12-hour dark daily cycles for 10 days. Then, seedlings of similar size were carefully transferred to pots filled with a mix of perlite and peat in a 1:1 ratio. Constant nitrogen limiting conditions were achieved by irrigating the plants with a solution containing 1.5 mM inorganic nitrogen in the form of KNO₃, supplemented with 2 mM CaCl₂, 1.25 mM KH₂PO₄, 1.50 mM MgSO₄, 5 mM KCl, 0.01 mM H₃BO₃ and microelements, while normal irrigation conditions was achieved by applying a solution of 6 mM inorganic nitrogen also in the form of KNO₃, supplemented with 2 mM CaCl₂, 1.25 mM KH₂PO₄, 1.50 mM MgSO₄, 0.01 mM H₃BO₃ and microelements. To follow plant growth, trays were photographed the day nitrogen limiting conditions were initiated and subsequently every 3 days for about 15 additional days. Rosette plant area was then determined from the digital pictures. ImageJ software was used for quantifying the plant size from the digital pictures [Hypertext Transfer Protocol://rsb (dot) info (dot) nih (dot) gov/ij] utilizing proprietary scripts designed to analyze the size of rosette area from individual plants as a function of time. The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Data parameters collected are summarized in Table 4, hereinbelow.

TABLE 4 Arabidopsis correlated parameters (vectors) Correlated parameter with Correlation Id N 1.5 mM; Rosette Area at day 8 [cm²] 1 N 1.5 mM; Rosette Area at day 10 [cm²] 2 N 1.5 mM; Plot Coverage at day 8 [%] 3 N 1.5 mM; Plot Coverage at day 10 [%] 4 N 1.5 mM; Leaf Number at day 10 5 N 1.5 mM; Leaf Blade Area at day 10 [cm²] 6 N 1.5 mM; RGR of Rosette Area at day 3 [cm²/day] 7 N 1.5 mM; t50 Flowering [day] 8 N 1.5 mM; Dry Weight [gr/plant] 9 N 1.5 mM; Seed Yield [gr/plant] 10 N 1.5 mM; Harvest Index 11 N 1.5 mM; 1000 Seeds weight [gr] 12 N 1.5 mM; seed yield/rosette area at day 10 [gr/cm²] 13 N 1.5 mM; seed yield/leaf blade [gr/cm²] 14 N 1.5 mM; % Seed yield reduction compared to N 6 mM 15 N 1.5 mM; % Biomass reduction compared to N 6 mM 16 N 1.5 mM; N level/DW [SPAD unit/gr] 17 N 1.5 mM; DW/N level [gr/SPAD unit] 18 N 1.5 mM; seed yield/N level [gr/SPAD unit] 19 N 6 mM; Rosette Area at day 8 [cm²] 20 N 6 mM; Rosette Area at day 10 [cm²] 21 N 6 mM; Plot Coverage at day 8 [%] 22 N 6 mM; Plot Coverage at day 10 [%] 23 N 6 mM; Leaf Number at day 10 24 N 6 mM; Leaf Blade Area at day 10 25 N 6 mM; RGR of Rosette Area at day 3 [cm²/gr] 26 N 6 mM; t50 Flowering [day] 27 N 6 mM; Dry Weight [gr/plant] 28 N 6 mM; Seed Yield [gr/plant] 29 N 6 mM; Harvest Index 30 N 6 mM; 1000 Seeds weight [gr] 31 N 6 mM; seed yield/rosette area day at day 10 [gr/cm²] 32 N 6 mM; seed yield/leaf blade [gr/cm²] 33 N 6 mM; N level/FW 34 N 6 mM; DW/N level [gr/SPAD unit] 35 N 6 mM; N level/DW (SPAD unit/gr plant) 36 N 6 mM; Seed yield/N unit [gr/SPAD unit] 37 Table 4. “N” = Nitrogen at the noted concentrations; “gr.” = grams; “SPAD” = chlorophyll levels; “t50” = time where 50% of plants flowered; “gr/SPAD unit” = plant biomass expressed in grams per unit of nitrogen in plant measured by SPAD. “DW” = plant dry weight; “N level/DW” = plant Nitrogen level measured in SPAD unit per plant biomass [gr]; “DW/N level” = plant biomass per plant [gr]/SPAD unit; “RGR” = relative growth rate;

Assessment of NUE, yield components and vigor-related parameters—Ten Arabidopsis ecotypes were grown in trays, each containing 8 plants per plot, in a greenhouse with controlled temperature conditions for about 12 weeks. Plants were irrigated with different nitrogen concentration as described above depending on the treatment applied. During this time, data was collected documented and analyzed. Most of chosen parameters were analyzed by digital imaging.

Digital Imaging—Greenhouse Assay

An image acquisition system, which consists of a digital reflex camera (Canon EOS 400D) attached with a 55 mm focal length lens (Canon EF-S series) placed in a custom made Aluminum mount, was used for capturing images of plants planted in containers within an environmental controlled greenhouse. The image capturing process is repeated every 2-3 days starting at day 9-12 till day 16-19 (respectively) from transplanting.

An image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data was calculated, including leaf number, leaf blade area, Rosette diameter and area.

Relative growth area rate: The relative growth rate of the rosette and the leaves was calculated according to Formula II as described above.

Seed yield and 1000 seeds weight—At the end of the experiment all seeds from all plots were collected and weighed in order to measure seed yield per plant in terms of total seed weight per plant (gr). For the calculation of 1000 seed weight, an average weight of 0.02 grams was measured from each sample, the seeds were scattered on a glass tray and a picture was taken. Using the digital analysis, the number of seeds in each sample was calculated.

Dry weight and seed yield—At the end of the experiment, plant were harvested and left to dry at 30° C. in a drying chamber. The biomass was separated from the seeds, weighed and divided by the number of plants. Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 30° C. in a drying chamber.

Harvest Index—The harvest index was calculated using Formula IV as described above.

T₅₀ days to flowering—Each of the repeats was monitored for flowering date. Days of flowering was calculated from sowing date till 50% of the plots flowered. Plant nitrogen level—The chlorophyll content of leaves is a good indicator of the nitrogen plant status since the degree of leaf greenness is highly correlated to this parameter. Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at time of flowering. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot. Based on this measurement, parameters such as the ratio between seed yield per nitrogen unit [seed yield/N level=seed yield per plant [gr]/SPAD unit], plant DW per nitrogen unit [DW/N level=plant biomass per plant [g]/SPAD unit], and nitrogen level per gram of biomass [N level/DW=SPAD unit/plant biomass per plant (gr)] were calculated.

Percent of seed yield reduction—measures the amount of seeds obtained in plants when grown under nitrogen-limiting conditions compared to seed yield produced at normal nitrogen levels expressed in %.

Experimental Results

10 different Arabidopsis accessions (ecotypes) were grown and characterized for 37 parameters as described above. The average for each of the measured parameters was calculated using the JMP software and values are summarized in Table 5 below. Subsequent correlation analysis between the various transcriptom sets (Table 3) and the measured parameters was conducted (Tables 6 and 7 below). Following are the results integrated to the database.

TABLE 5 Measured parameters in Arabidopsis accessions Ecotype Treatment Line-1 Line-2 Line-3 Line-4 Line-5 Line-6 Line-7 Line-8 Line-9 Line-10 N 1.5 mM; Rosette Area at day 8 0.760 0.709 1.061 1.157 0.996 1.000 0.910 0.942 1.118 0.638 N 1.5 mM; Rosette Area at day 10 1.430 1.325 1.766 1.971 1.754 1.832 1.818 1.636 1.996 1.150 N 1.5 mM; Plot Coverage % at day 8 3.221 3.003 4.497 4.902 4.220 4.238 3.858 3.990 4.738 2.705 N 1.5 mM; Plot Coverage % at day 10 6.058 5.614 7.484 8.351 7.432 7.764 7.702 6.933 8.458 4.871 N 1.5 mM; Leaf Number at day 10 6.875 7.313 7.313 7.875 7.938 7.750 7.625 7.188 8.625 5.929 N 1.5 mM; Leaf Blade Area at day 10 0.335 0.266 0.374 0.387 0.373 0.370 0.386 0.350 0.379 0.307 N 1.5 mM; RGR of Rosette Area at day 3 0.631 0.793 0.502 0.491 0.605 0.720 0.825 0.646 0.668 0.636 N 1.5 mM; t50 Flowering [day] 15.967 20.968 14.836 24.708 23.566 23.698 18.059 19.488 23.568 21.888 N 1.5 mM; Dry Weight [gr/plant] 0.164 0.124 0.082 0.113 0.184 0.124 0.134 0.106 0.148 0.171 N 1.5 mM; Seed Yield [gr/plant] 0.032 0.025 0.023 0.010 0.006 0.009 0.032 0.019 0.012 0.014 N 1.5 mM; Harvest Index 0.192 0.203 0.295 0.085 0.031 0.071 0.241 0.179 0.081 0.079 N 1.5 mM; 1000 Seeds weight[gr] 0.016 0.016 0.018 0.014 0.018 0.022 0.015 0.014 0.022 0.019 N 1.5 mM; seed yield/rosette area day at day 10 0.022 0.019 0.014 0.005 0.003 0.005 0.018 0.013 0.007 0.012 N 1.5 mM; seed yield/leaf blade 0.095 0.095 0.063 0.026 0.015 0.024 0.084 0.059 0.034 0.044 N 1.5 mM; % Seed yield reduction compared to 6 mM 72.559 84.701 78.784 87.996 91.820 92.622 76.710 81.938 91.301 85.757 N 1.5 mM; % Biomass reduction compared to 6 mM 60.746 76.706 78.560 78.140 62.972 78.641 73.192 83.068 77.190 70.120 N 1.5 mM; Spad/FW 45.590 42.108 28.151 53.111 67.000 N 1.5 mM; SPAD/DW 167.300 241.061 157.823 194.977 169.343 N 1.5 mM; DW/SPAD 0.006 0.004 0.006 0.005 0.006 N 1.5 mM; seed yield/spad 0.001 0.000 0.000 0.001 0.000 N 6 mM; Rosette Area at day 8 0.759 0.857 1.477 1.278 1.224 1.095 1.236 1.094 1.410 0.891 N 6 mM; Rosette Area at day 10 1.406 1.570 2.673 2.418 2.207 2.142 2.474 1.965 2.721 1.642 N 6 mM; Plot Coverage % at day 8 3.216 3.631 6.259 5.413 5.187 4.641 5.236 4.634 5.974 3.774 N 6 mM; Plot Coverage % at day 10 5.957 6.654 11.324 10.244 9.352 9.076 10.485 8.327 11.528 6.958 N 6 mM; Leaf Number at day 10 6.250 7.313 8.063 8.750 8.063 8.750 8.375 7.125 9.438 6.313 N 6 mM; Leaf Blade Area at day 10 0.342 0.315 0.523 0.449 0.430 0.430 0.497 0.428 0.509 0.405 N 6 mM; RGR of Rosette Area at day 3 0.689 1.024 0.614 0.601 0.477 0.651 0.676 0.584 0.613 0.515 N 6 mM; t50 Flowering [day] 16.371 20.500 14.635 24.000 23.378 23.595 15.033 19.750 22.887 18.804 N 6 mM; Dry Weight [gr/plant] 0.419 0.531 0.382 0.518 0.496 0.579 0.501 0.628 0.649 0.573 N 6 mM; Seed Yield [gr/plant] 0.116 0.165 0.108 0.082 0.068 0.119 0.139 0.107 0.138 0.095 N 6 mM; Harvest Index 0.280 0.309 0.284 0.158 0.136 0.206 0.276 0.171 0.212 0.166 N 6 mM; 1000 Seeds weight[gr] 0.015 0.017 0.018 0.012 0.016 0.016 0.015 0.014 0.017 0.016 N 6 mM; seed yield/rosette area day at day 10 0.082 0.106 0.041 0.034 0.031 0.056 0.057 0.055 0.051 0.058 N 6 mM; seed yield/leaf blade 0.339 0.526 0.207 0.183 0.158 0.277 0.281 0.252 0.271 0.235 N 6 mM; Spad/FW 22.489 28.268 17.641 33.323 39.003 N 6 mM; DW/SPAD (biomass/N unit) 0.019 0.018 0.028 0.015 0.015 N 6 mM; spad/DW (gN/g plant) 53.705 54.625 35.548 66.479 68.054 N 6 mM; Seed yield/N unit 0.004 0.003 0.002 0.005 0.003 Table 5. Provided are the measured parameters under various treatments in various ecotypes (Arabidopsis accessions). “RGR” = relative growth rate;

TABLE 6 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under normal or low nitrogen fertilization conditions across Arabidopsis accessions Exp. Correl. Exp. Correl. Gene Name R P value set Set ID Gene Name R P value set Set ID LNU1 0.78 7.86E−03 A 6 LNU182 0.73 1.70E−02 A 8 LNU1 0.76 1.80E−02 C 5 LNU182 0.75 1.20E−02 A 8 LNU1 0.75 1.33E−02 A 2 LNU182 0.75 2.09E−02 C 8 LNU1 0.80 4.98E−03 A 1 LNU182 0.76 1.04E−02 C 8 LNU1 0.74 1.35E−02 A 1 LNU182 0.84 2.12E−03 B 24 LNU1 0.72 2.87E−02 C 1 LNU182 0.81 4.08E−03 B 24 LNU1 0.83 3.20E−03 B 25 LNU182 0.91 6.63E−04 D 24 LNU1 0.83 2.96E−03 B 21 LNU182 0.78 8.39E−03 D 24 LNU1 0.86 1.27E−03 B 20 LNU182 0.75 1.17E−02 B 27 LNU1 0.97 4.77E−03 B 35 LNU182 0.73 1.66E−02 B 27 LNU1 0.91 3.24E−02 B 35 LNU182 0.79 6.67E−03 D 27 LNU123 0.90 3.72E−02 A 18 LNU183 0.80 5.90E−03 C 10 LNU123 0.89 4.05E−02 B 35 LNU183 0.80 5.89E−03 C 14 LNU124 0.87 9.30E−04 A 11 LNU183 0.79 6.13E−03 C 13 LNU124 0.81 7.91E−03 C 11 LNU183 0.71 2.06E−02 B 31 LNU124 0.91 2.70E−04 C 11 LNU183 0.80 5.94E−03 D 30 LNU124 0.72 1.95E−02 A 10 LNU183 0.72 2.94E−02 D 32 LNU124 0.91 2.78E−04 A 10 LNU184 0.87 1.08E−03 C 11 LNU124 0.83 6.08E−03 C 10 LNU184 0.89 4.09E−02 C 19 LNU124 0.89 6.50E−04 C 10 LNU184 0.88 4.83E−02 B 37 LNU124 0.96 9.63E−03 A 19 LNU184 0.93 1.98E−02 B 37 LNU124 0.98 2.55E−03 C 19 LNU184 0.93 2.08E−02 D 37 LNU124 0.84 2.31E−03 A 14 LNU184 0.89 4.04E−02 B 36 LNU124 0.75 1.96E−02 C 14 LNU185 0.99 1.83E−03 C 18 LNU124 0.89 5.45E−04 C 14 LNU186 0.72 1.88E−02 C 15 LNU124 0.86 1.25E−03 A 13 LNU186 0.84 2.46E−03 C 8 LNU124 0.79 1.20E−02 C 13 LNU186 0.73 1.71E−02 D 27 LNU124 0.85 2.04E−03 C 13 LNU187 0.82 6.47E−03 D 26 LNU124 0.81 4.19E−03 B 30 LNU187 0.74 2.18E−02 D 33 LNU124 0.89 6.61E−04 D 30 LNU187 0.88 4.65E−02 B 37 LNU124 0.92 2.79E−02 B 37 LNU206 0.72 1.82E−02 C 16 LNU124 0.94 1.63E−02 D 37 LNU206 0.71 2.02E−02 C 16 LNU124 0.76 1.06E−02 A 11 LNU206 0.71 2.05E−02 A 2 LNU125 0.72 1.80E−02 A 11 LNU206 0.84 2.24E−03 A 1 LNU125 0.81 4.61E−03 A 10 LNU206 0.82 3.92E−03 A 1 LNU125 0.83 3.17E−03 A 10 LNU206 0.75 1.24E−02 B 20 LNU125 0.84 4.66E−03 C 10 LNU206 0.72 1.90E−02 B 20 LNU125 0.95 1.30E−02 A 19 LNU207 0.79 6.36E−03 A 11 LNU125 0.88 4.88E−02 C 19 LNU210 0.73 2.64E−02 C 11 LNU125 0.82 3.78E−03 A 14 LNU210 0.74 1.36E−02 A 10 LNU125 0.78 7.43E−03 A 14 LNU210 0.70 2.33E−02 A 10 LNU125 0.83 5.88E−03 C 14 LNU210 0.74 1.38E−02 A 14 LNU125 0.72 1.84E−02 A 13 LNU210 0.73 1.67E−02 A 14 LNU125 0.72 1.96E−02 A 13 LNU210 0.72 1.87E−02 A 14 LNU125 0.82 6.30E−03 C 13 LNU210 0.78 8.31E−03 A 13 LNU125 0.82 3.37E−03 B 30 LNU210 0.74 1.45E−02 A 13 LNU125 0.92 1.78E−04 B 30 LNU210 0.73 1.62E−02 A 13 LNU125 0.71 2.11E−02 D 30 LNU210 0.74 1.49E−02 B 30 LNU125 0.79 5.99E−03 B 26 LNU210 0.71 2.18E−02 B 30 LNU125 0.78 7.61E−03 B 29 LNU211 0.82 3.68E−03 C 15 LNU125 0.78 8.34E−03 B 29 LNU211 0.77 9.05E−03 C 15 LNU125 0.91 3.07E−02 B 37 LNU211 0.89 5.65E−04 C 8 LNU125 0.91 3.16E−02 B 37 LNU211 0.84 2.25E−03 C 8 LNU126 0.77 9.60E−03 A 11 LNU211 0.80 4.99E−03 D 27 LNU126 0.76 1.13E−02 C 11 LNU211 0.77 8.96E−03 D 27 LNU126 0.87 1.01E−03 A 10 LNU213 0.75 1.26E−02 C 9 LNU126 0.74 2.28E−02 C 10 LNU213 0.76 1.07E−02 A 8 LNU126 0.93 1.08E−04 C 10 LNU213 0.75 1.17E−02 B 27 LNU126 0.92 2.83E−02 C 19 LNU215 0.80 5.41E−03 A 11 LNU126 0.83 3.21E−03 A 14 LNU215 0.77 9.84E−03 A 11 LNU126 0.72 3.00E−02 C 14 LNU215 0.85 1.72E−03 C 11 LNU126 0.94 4.77E−05 C 14 LNU215 0.75 1.16E−02 C 11 LNU126 0.87 1.05E−03 A 13 LNU215 0.76 1.09E−02 A 7 LNU126 0.78 1.31E−02 C 13 LNU215 0.74 1.49E−02 A 7 LNU126 0.95 3.71E−05 C 13 LNU215 0.90 3.85E−04 A 10 LNU126 0.94 1.81E−02 A 17 LNU215 0.89 6.05E−04 A 10 LNU126 0.74 1.35E−02 B 30 LNU215 0.77 8.62E−03 C 10 LNU126 0.88 9.14E−04 D 30 LNU215 0.91 3.00E−02 A 19 LNU126 0.72 1.94E−02 D 32 LNU215 0.91 3.33E−02 A 19 LNU126 0.91 3.13E−02 B 36 LNU215 0.95 1.52E−02 C 19 LNU127 0.73 1.55E−02 A 12 LNU215 0.90 4.04E−04 A 14 LNU127 0.81 4.57E−03 A 11 LNU215 0.87 9.88E−04 A 14 LNU127 0.87 2.17E−03 C 11 LNU215 0.86 1.39E−03 A 13 LNU127 0.81 8.03E−03 C 11 LNU215 0.84 2.45E−03 A 13 LNU127 0.74 1.49E−02 C 11 LNU215 0.90 4.13E−04 B 30 LNU127 0.85 3.93E−03 C 10 LNU215 0.82 3.99E−03 B 30 LNU127 0.75 1.95E−02 C 10 LNU215 0.71 2.18E−02 B 26 LNU127 0.79 6.97E−03 C 10 LNU218 0.82 7.15E−03 C 11 LNU127 0.90 3.54E−02 A 19 LNU218 0.74 2.21E−02 C 11 LNU127 0.92 2.63E−02 C 19 LNU218 0.70 2.31E−02 C 11 LNU127 0.79 1.13E−02 C 14 LNU218 0.73 1.75E−02 A 14 LNU127 0.77 9.09E−03 C 14 LNU218 0.74 1.42E−02 A 14 LNU127 0.80 9.01E−03 C 13 LNU218 0.72 2.72E−02 C 14 LNU127 0.78 7.52E−03 C 13 LNU218 0.74 1.41E−02 C 14 LNU127 0.73 1.73E−02 C 13 LNU218 0.75 1.19E−02 A 13 LNU127 0.89 4.17E−02 A 17 LNU218 0.76 1.05E−02 A 13 LNU127 0.76 1.08E−02 B 30 LNU218 0.72 3.01E−02 C 13 LNU127 0.83 5.36E−03 D 30 LNU218 0.78 7.56E−03 C 13 LNU127 0.81 7.93E−03 D 30 LNU219 0.79 6.18E−03 C 16 LNU127 0.90 3.61E−02 B 37 LNU219 0.74 1.41E−02 C 16 LNU127 0.89 4.37E−02 B 36 LNU219 0.78 7.39E−03 A 2 LNU127 0.92 2.87E−02 B 34 LNU219 0.76 1.13E−02 A 2 LNU128 0.77 9.80E−03 A 11 LNU219 0.81 4.95E−03 A 1 LNU128 0.76 1.13E−02 A 11 LNU219 0.79 6.02E−03 A 1 LNU128 0.81 4.54E−03 C 11 LNU219 0.97 4.90E−03 A 17 LNU128 0.72 1.85E−02 A 10 LNU219 0.96 8.96E−03 A 17 LNU128 0.97 7.59E−03 A 19 LNU219 0.74 2.26E−02 D 25 LNU128 0.95 1.40E−02 A 19 LNU219 0.74 2.40E−02 D 25 LNU128 0.96 1.12E−02 C 19 LNU219 0.74 1.35E−02 B 24 LNU128 0.79 6.18E−03 B 30 LNU219 0.71 2.14E−02 B 24 LNU128 0.73 1.73E−02 B 30 LNU219 0.78 1.40E−02 D 24 LNU128 0.80 9.72E−03 D 30 LNU219 0.77 1.45E−02 D 24 LNU128 0.79 1.22E−02 D 29 LNU219 0.74 1.53E−02 D 24 LNU128 0.91 3.39E−02 B 37 LNU219 0.73 1.76E−02 D 24 LNU128 0.96 1.03E−02 B 37 LNU219 0.78 7.47E−03 B 21 LNU129 0.74 1.46E−02 A 16 LNU219 0.72 1.97E−02 B 21 LNU129 0.70 2.35E−02 A 16 LNU219 0.78 1.36E−02 D 21 LNU129 0.82 6.97E−03 C 11 LNU219 0.77 1.46E−02 D 21 LNU129 0.81 4.89E−03 C 11 LNU219 0.72 1.83E−02 B 20 LNU129 0.79 5.99E−03 C 11 LNU219 0.70 2.31E−02 B 20 LNU129 0.79 1.12E−02 C 10 LNU219 0.75 1.30E−02 B 20 LNU129 0.73 2.65E−02 C 14 LNU225 0.76 1.15E−02 A 12 LNU129 0.73 2.56E−02 C 13 LNU225 0.71 2.08E−02 A 5 LNU129 0.95 1.29E−02 A 17 LNU225 0.71 2.22E−02 A 5 LNU129 0.94 1.61E−02 A 17 LNU225 0.79 6.89E−03 A 2 LNU129 0.92 2.87E−02 A 17 LNU225 0.82 4.02E−03 A 2 LNU129 0.73 2.48E−02 D 30 LNU225 0.80 5.59E−03 A 2 LNU130 0.87 1.05E−03 A 11 LNU225 0.78 8.33E−03 A 2 LNU130 0.92 1.88E−04 A 10 LNU225 0.80 1.03E−02 C 2 LNU130 0.96 1.13E−02 A 19 LNU225 0.77 1.50E−02 C 2 LNU130 0.89 4.83E−04 A 14 LNU225 0.76 1.06E−02 C 2 LNU130 0.89 5.74E−04 A 13 LNU225 0.74 1.49E−02 C 2 LNU130 0.85 1.96E−03 B 30 LNU225 0.73 1.76E−02 C 2 LNU130 0.78 8.11E−03 D 26 LNU225 0.75 1.22E−02 A 1 LNU130 0.73 1.70E−02 D 33 LNU225 0.75 1.30E−02 A 1 LNU130 0.97 6.99E−03 B 37 LNU225 0.74 2.23E−02 C 1 LNU131 0.77 8.68E−03 A 6 LNU225 0.73 1.66E−02 C 1 LNU131 0.75 1.26E−02 A 6 LNU225 0.99 7.77E−04 A 17 LNU131 0.81 4.74E−03 A 2 LNU225 0.95 1.23E−02 A 17 LNU131 0.80 5.22E−03 A 2 LNU225 0.98 2.52E−03 A 17 LNU131 0.86 1.29E−03 A 1 LNU225 0.98 2.54E−03 A 17 LNU131 0.82 3.59E−03 A 1 LNU225 0.99 5.55E−04 C 17 LNU131 0.92 2.64E−02 A 17 LNU225 0.99 1.27E−03 C 17 LNU131 0.88 4.64E−02 A 17 LNU225 0.89 4.56E−02 C 17 LNU131 0.81 4.18E−03 B 25 LNU225 0.82 3.45E−03 B 24 LNU131 0.74 1.40E−02 B 25 LNU225 0.80 5.23E−03 B 24 LNU131 0.82 3.65E−03 B 24 LNU225 0.82 3.67E−03 B 24 LNU131 0.70 2.33E−02 B 24 LNU225 0.75 1.23E−02 B 24 LNU131 0.84 2.46E−03 B 21 LNU225 0.75 1.26E−02 B 24 LNU131 0.75 1.16E−02 B 21 LNU225 0.78 1.24E−02 D 24 LNU131 0.79 6.07E−03 B 20 LNU225 0.83 3.21E−03 D 24 LNU131 0.74 1.36E−02 B 20 LNU225 0.81 4.76E−03 D 24 LNU131 0.95 1.41E−02 B 35 LNU225 0.77 8.51E−03 D 24 LNU131 0.91 3.29E−02 B 35 LNU234 0.92 1.64E−04 A 11 LNU132 0.94 3.82E−05 A 11 LNU234 0.76 1.03E−02 A 11 LNU132 0.72 2.85E−02 C 11 LNU234 0.83 2.68E−03 C 11 LNU132 0.78 8.12E−03 C 11 LNU234 0.83 3.05E−03 C 11 LNU132 0.72 1.81E−02 A 10 LNU234 0.80 5.47E−03 A 10 LNU132 0.84 2.47E−03 A 10 LNU234 0.85 3.92E−03 C 10 LNU132 0.79 6.66E−03 C 10 LNU234 0.97 5.68E−03 A 19 LNU132 0.94 1.85E−02 A 19 LNU234 0.97 6.49E−03 C 19 LNU132 0.76 1.00E−02 A 14 LNU234 0.96 1.08E−02 C 19 LNU132 0.72 1.84E−02 C 14 LNU234 0.81 8.21E−03 C 14 LNU132 0.74 1.49E−02 A 13 LNU234 0.81 8.76E−03 C 13 LNU132 0.74 1.44E−02 C 13 LNU234 0.94 1.95E−02 A 17 LNU132 0.72 1.89E−02 B 30 LNU234 0.89 4.23E−02 A 17 LNU132 0.89 4.59E−02 B 37 LNU234 0.90 3.87E−02 C 17 LNU132 0.97 7.13E−03 B 37 LNU234 0.90 8.60E−04 D 30 LNU133 0.76 1.12E−02 A 7 LNU234 0.79 1.05E−02 D 30 LNU133 0.71 2.03E−02 A 7 LNU234 0.87 1.12E−03 D 30 LNU133 0.81 7.58E−03 C 7 LNU234 0.82 4.00E−03 D 30 LNU133 0.81 4.47E−03 C 7 LNU234 0.83 5.75E−03 D 29 LNU133 0.82 3.45E−03 B 29 LNU234 0.76 1.69E−02 D 29 LNU133 0.77 9.67E−03 B 29 LNU234 0.75 2.09E−02 D 29 LNU133 0.85 3.64E−03 D 29 LNU234 0.74 2.30E−02 D 32 LNU133 0.79 7.02E−03 D 29 LNU234 0.72 2.75E−02 D 33 LNU133 0.89 4.18E−02 D 37 LNU234 0.97 6.94E−03 B 37 LNU134 0.70 2.42E−02 A 12 LNU234 0.95 1.25E−02 D 37 LNU134 0.74 1.39E−02 A 7 LNU234 0.89 4.04E−02 D 37 LNU134 0.73 1.69E−02 A 7 LNU234 0.91 3.01E−02 D 36 LNU134 0.75 2.08E−02 C 7 LNU235 0.74 1.44E−02 A 11 LNU134 0.72 1.85E−02 C 2 LNU235 0.73 1.66E−02 A 11 LNU134 0.98 2.66E−03 A 17 LNU235 0.76 1.06E−02 C 11 LNU134 0.73 2.51E−02 D 30 LNU235 0.73 1.70E−02 A 10 LNU134 0.80 5.04E−03 B 24 LNU235 0.73 1.75E−02 A 14 LNU134 0.83 3.21E−03 B 24 LNU235 0.73 2.43E−02 C 14 LNU134 0.76 1.85E−02 D 24 LNU235 0.78 8.39E−03 A 13 LNU134 0.83 2.67E−03 D 24 LNU235 0.79 1.20E−02 D 30 LNU134 0.77 9.31E−03 B 26 LNU235 0.86 2.99E−03 D 26 LNU134 0.79 6.09E−03 B 26 LNU235 0.83 5.85E−03 D 32 LNU134 0.86 3.03E−03 D 26 LNU235 0.84 4.39E−03 D 33 LNU134 0.80 5.60E−03 D 26 LNU24 0.71 2.18E−02 A 11 LNU134 0.82 3.60E−03 B 29 LNU24 0.85 1.97E−03 A 11 LNU134 0.79 6.62E−03 B 29 LNU24 0.78 7.95E−03 C 11 LNU134 0.87 2.40E−03 D 29 LNU24 0.71 2.01E−02 A 10 LNU134 0.72 1.96E−02 D 29 LNU24 0.73 1.60E−02 A 10 LNU134 0.71 2.04E−02 B 32 LNU24 0.79 1.15E−02 C 10 LNU134 0.86 1.49E−03 B 32 LNU24 0.93 2.40E−02 A 19 LNU134 0.85 3.42E−03 D 32 LNU24 0.77 9.72E−03 A 8 LNU134 0.86 1.25E−03 D 32 LNU24 0.73 1.73E−02 B 27 LNU134 0.82 3.64E−03 B 33 LNU242 0.82 3.31E−03 A 7 LNU134 0.89 5.09E−04 B 33 LNU242 0.71 2.09E−02 A 7 LNU134 0.91 7.35E−04 D 33 LNU242 0.88 1.66E−03 C 7 LNU134 0.89 5.29E−04 D 33 LNU242 0.71 2.27E−02 C 7 LNU135 0.85 1.71E−03 A 11 LNU242 0.70 3.46E−02 C 10 LNU135 0.72 1.90E−02 A 10 LNU242 0.91 3.06E−02 C 17 LNU135 0.93 2.21E−02 C 17 LNU242 0.85 1.63E−03 B 29 LNU136 0.79 6.32E−03 A 11 LNU242 0.81 4.09E−03 B 29 LNU136 0.96 7.92E−03 A 17 LNU242 0.83 6.09E−03 D 29 LNU136 0.95 1.21E−02 A 17 LNU242 0.87 9.49E−04 D 29 LNU136 0.90 3.77E−02 C 17 LNU247 0.78 8.28E−03 A 12 LNU136 0.78 1.41E−02 D 30 LNU247 0.85 1.84E−03 A 12 LNU136 0.88 8.99E−04 B 26 LNU247 0.75 1.94E−02 C 12 LNU136 0.80 5.26E−03 B 33 LNU247 0.80 4.99E−03 C 12 LNU136 0.93 2.21E−02 D 37 LNU249 0.70 2.28E−02 A 11 LNU14 0.92 2.50E−02 C 17 LNU249 0.85 3.90E−03 C 7 LNU14 0.72 1.89E−02 B 25 LNU249 0.87 1.07E−03 A 10 LNU14 0.91 3.18E−02 D 36 LNU249 0.95 1.35E−02 A 19 LNU140 0.93 2.06E−02 C 18 LNU249 0.95 1.78E−05 A 14 LNU140 0.81 7.85E−03 C 7 LNU249 0.92 1.31E−04 A 13 LNU140 0.97 7.30E−03 A 19 LNU249 0.83 2.68E−03 B 30 LNU140 0.77 9.73E−03 A 8 LNU249 0.82 6.70E−03 D 30 LNU140 0.85 1.72E−03 B 26 LNU249 0.75 1.88E−02 D 30 LNU140 0.74 1.42E−02 B 29 LNU249 0.71 2.07E−02 B 26 LNU140 0.78 1.24E−02 D 29 LNU249 0.81 4.45E−03 B 26 LNU140 0.81 4.46E−03 B 32 LNU249 0.80 9.94E−03 D 26 LNU140 0.75 2.12E−02 D 32 LNU249 0.80 5.30E−03 B 29 LNU140 0.89 5.19E−04 B 33 LNU249 0.74 1.42E−02 B 29 LNU140 0.76 1.65E−02 D 33 LNU249 0.82 7.33E−03 D 29 LNU140 0.96 1.09E−02 B 37 LNU249 0.81 8.47E−03 D 29 LNU140 0.75 1.26E−02 B 27 LNU249 0.80 5.30E−03 B 32 LNU15 0.70 2.30E−02 A 9 LNU249 0.85 1.90E−03 B 32 LNU170 0.74 1.40E−02 A 12 LNU249 0.74 2.31E−02 D 32 LNU170 0.76 1.66E−02 C 12 LNU249 0.82 3.37E−03 B 33 LNU170 0.73 1.71E−02 A 16 LNU249 0.83 3.29E−03 B 33 LNU170 0.73 1.59E−02 C 16 LNU249 0.79 1.18E−02 D 33 LNU170 0.82 4.00E−03 A 2 LNU249 0.90 3.49E−02 B 37 LNU170 0.79 6.10E−03 A 2 LNU250 0.78 7.39E−03 A 11 LNU170 0.80 9.44E−03 C 2 LNU250 0.71 2.17E−02 A 7 LNU170 0.79 6.07E−03 C 2 LNU250 0.79 6.58E−03 A 10 LNU170 0.88 8.83E−04 A 1 LNU250 0.95 3.35E−05 A 10 LNU170 0.88 6.87E−04 A 1 LNU250 0.91 3.18E−02 A 19 LNU170 0.84 4.72E−03 C 1 LNU250 0.97 6.08E−03 A 19 LNU170 0.87 9.86E−04 C 1 LNU250 0.83 2.77E−03 A 14 LNU170 0.81 8.77E−03 D 25 LNU250 0.93 7.59E−05 A 14 LNU170 0.74 1.45E−02 D 25 LNU250 0.83 2.76E−03 A 13 LNU170 0.81 4.61E−03 B 24 LNU250 0.92 1.63E−04 A 13 LNU170 0.78 8.26E−03 B 24 LNU250 0.70 3.50E−02 C 13 LNU170 0.73 1.72E−02 B 24 LNU250 0.80 5.53E−03 B 30 LNU170 0.80 9.62E−03 D 24 LNU250 0.78 7.75E−03 B 29 LNU170 0.78 7.72E−03 D 24 LNU250 0.71 2.09E−02 B 29 LNU170 0.80 5.86E−03 B 21 LNU250 0.82 3.82E−03 B 32 LNU170 0.81 4.63E−03 B 21 LNU250 0.75 1.17E−02 B 33 LNU170 0.90 9.72E−04 D 21 LNU250 0.91 3.17E−02 B 37 LNU170 0.86 1.38E−03 D 21 LNU250 0.95 1.24E−02 B 37 LNU170 0.80 5.15E−03 B 20 LNU251 0.75 1.32E−02 A 6 LNU170 0.84 2.62E−03 B 20 LNU251 0.79 6.02E−03 A 2 LNU170 0.90 1.04E−03 D 20 LNU251 0.72 1.96E−02 A 1 LNU170 0.89 6.02E−04 D 20 LNU251 0.73 1.68E−02 B 24 LNU175 0.80 5.82E−03 A 11 LNU251 0.92 2.57E−02 B 35 LNU175 0.90 3.34E−04 C 11 LNU254 0.84 2.37E−03 C 15 LNU175 0.98 3.47E−03 C 19 LNU254 0.88 8.39E−04 C 8 LNU175 0.93 2.38E−02 D 37 LNU254 0.82 4.01E−03 D 27 LNU175 0.88 4.60E−02 B 36 LNU255 0.78 8.00E−03 A 10 LNU175 0.91 2.97E−02 B 34 LNU255 0.89 4.54E−02 A 19 LNU177 0.75 1.21E−02 A 11 LNU255 0.91 3.16E−02 A 17 LNU177 0.73 1.66E−02 C 11 LNU255 0.96 8.73E−03 B 37 LNU177 0.73 1.68E−02 C 10 LNU255 0.99 5.16E−04 B 36 LNU177 0.79 6.51E−03 B 31 LNU255 0.92 2.49E−02 B 34 LNU177 0.86 1.60E−03 D 30 LNU255 0.91 3.34E−02 B 34 LNU177 0.77 9.90E−03 D 32 LNU256 0.76 1.78E−02 C 11 LNU179 0.80 5.62E−03 A 11 LNU256 0.78 7.59E−03 A 5 LNU179 0.87 9.87E−04 A 11 LNU256 0.78 1.32E−02 D 31 LNU179 0.90 4.59E−04 C 11 LNU256 0.71 2.19E−02 D 30 LNU179 0.76 1.15E−02 A 10 LNU256 0.71 2.05E−02 B 24 LNU179 0.92 1.92E−04 A 10 LNU257 0.85 1.75E−03 C 11 LNU179 0.72 1.95E−02 C 10 LNU257 0.74 1.43E−02 A 7 LNU179 0.96 1.11E−02 A 19 LNU257 0.73 1.70E−02 A 7 LNU179 0.91 3.44E−02 C 19 LNU257 0.82 4.07E−03 C 10 LNU179 0.84 2.27E−03 A 14 LNU257 0.90 3.65E−02 C 19 LNU179 0.83 2.82E−03 A 13 LNU257 0.82 3.37E−03 C 14 LNU179 0.97 6.67E−03 B 37 LNU257 0.83 2.91E−03 C 13 LNU180 0.79 6.02E−03 A 7 LNU257 0.81 4.78E−03 D 30 LNU180 0.76 1.04E−02 A 7 LNU258 0.75 1.31E−02 A 11 LNU180 0.72 1.92E−02 A 10 LNU258 0.79 6.36E−03 C 11 LNU180 0.77 1.46E−02 C 10 LNU258 0.76 1.01E−02 A 10 LNU180 0.91 3.24E−02 A 19 LNU258 0.80 5.41E−03 C 10 LNU180 0.93 1.99E−02 A 19 LNU258 0.92 2.45E−02 C 19 LNU180 0.92 2.57E−02 A 19 LNU258 0.79 6.92E−03 A 14 LNU180 0.70 2.41E−02 A 14 LNU258 0.87 1.11E−03 C 14 LNU180 0.74 2.29E−02 C 13 LNU258 0.83 2.76E−03 A 13 LNU180 0.92 2.74E−02 A 17 LNU258 0.86 1.56E−03 C 13 LNU180 0.86 1.55E−03 B 29 LNU258 0.76 1.09E−02 D 30 LNU180 0.81 4.45E−03 B 29 LNU260 0.86 1.39E−03 C 11 LNU180 0.99 2.08E−03 B 37 LNU260 0.91 2.73E−04 C 10 LNU180 0.88 4.67E−02 B 37 LNU260 0.93 2.34E−02 C 19 LNU180 0.98 4.69E−03 B 36 LNU260 0.88 7.70E−04 C 14 LNU180 0.89 4.53E−02 B 34 LNU260 0.84 2.42E−03 C 13 LNU181 0.72 1.80E−02 A 2 LNU260 0.78 8.14E−03 D 30 LNU181 0.80 5.37E−03 A 1 LNU260 0.97 7.52E−03 D 37 LNU181 0.74 1.46E−02 A 15 LNU261 0.75 1.20E−02 A 12 LNU181 0.82 4.04E−03 B 24 LNU261 0.75 1.32E−02 A 12 LNU181 0.75 1.29E−02 B 21 LNU261 0.83 2.88E−03 A 6 LNU181 0.76 1.05E−02 B 20 LNU261 0.78 7.38E−03 A 1 LNU181 0.91 3.17E−02 B 35 LNU261 0.73 2.66E−02 D 31 LNU182 0.71 3.32E−02 C 11 LNU261 0.71 3.36E−02 D 31 LNU182 0.71 2.09E−02 A 6 LNU261 0.71 2.24E−02 B 25 LNU182 0.79 6.26E−03 A 5 LNU261 0.71 2.04E−02 B 24 LNU182 0.71 2.28E−02 A 5 LNU261 0.80 5.03E−03 B 21 LNU182 0.97 8.06E−06 C 5 LNU261 0.84 2.50E−03 B 20 LNU182 0.78 7.68E−03 C 5 LNU261 0.94 1.78E−02 B 35 LNU182 0.78 7.95E−03 A 2 LNU262 0.83 3.15E−03 A 12 LNU182 0.79 6.72E−03 A 2 LNU262 0.78 1.34E−02 C 2 LNU182 0.80 1.04E−02 C 2 LNU262 0.79 6.53E−03 A 15 LNU182 0.72 1.96E−02 C 2 LNU262 0.80 5.50E−03 A 15 LNU182 0.76 1.14E−02 A 1 LNU262 0.73 1.62E−02 C 15 LNU182 0.77 8.53E−03 A 1 LNU262 0.72 1.97E−02 A 8 LNU182 0.75 2.05E−02 C 1 LNU262 0.88 8.15E−04 A 8 LNU182 0.71 2.03E−02 C 1 LNU262 0.85 1.74E−03 C 8 LNU182 0.77 8.65E−03 A 15 LNU262 0.81 7.58E−03 D 24 LNU182 0.75 1.33E−02 A 15 LNU262 0.70 2.37E−02 B 27 LNU182 0.82 6.29E−03 C 15 LNU262 0.85 2.02E−03 B 27 LNU182 0.82 3.37E−03 C 15 LNU8 0.75 2.09E−02 C 5 Table 6. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

TABLE 7 Correlation between the expression level of selected LNU orthologs genes of some embodiments of the invention in various tissues and the phenotypic performance under normal or low nitrogen fertilization conditions across Arabidopsis accessions Exp. Correl. Exp. Correl. Gene Name R P value Set Set ID Gene Name R P value Set Set ID LNU219_H1 0.88 6.94E−04 B 12 LNU45_H11 0.91 3.06E−02 A 17 LNU76_H3 0.77 9.83E−03 B 12 LNU46_H3 0.89 4.47E−02 A 17 LNU219_H1 0.71 2.17E−02 B 15 LNU46_H3 0.91 3.04E−02 B 36 LNU256_H0 0.96 1.14E−02 B 17 LNU219_H1 0.76 1.66E−02 D 27 LNU219_H1 0.79 7.10E−03 C 15 LNU219_H1 0.78 7.31E−03 C 27 LNU76_H3 0.74 1.45E−02 B 31 LNU7_H5 0.96 9.76E−03 B 35 LNU76_H3 0.70 2.40E−02 B 28 LNU219_H1 0.76 1.77E−02 D 5 LNU46_H5 0.73 1.67E−02 B 28 LNU7_H5 0.70 3.41E−02 D 5 LNU7_H5 0.70 2.32E−02 A 25 LNU7_H4 0.79 1.08E−02 D 5 LNU7_H4 0.83 2.75E−03 A 25 LNU219_H1 0.70 3.47E−02 D 5 LNU7_H4 0.80 5.94E−03 C 25 LNU219_H1 0.71 3.13E−02 D 1 LNU7_H4 0.71 2.13E−02 A 24 LNU7_H5 0.70 3.42E−02 D 1 LNU45_H9 0.78 7.80E−03 C 24 LNU7_H5 0.70 3.56E−02 D 1 LNU24_H2 0.90 4.44E−04 B 26 LNU219_H1 0.79 1.17E−02 D 8 LNU45_H11 0.90 4.44E−04 B 26 LNU7_H5 0.95 1.43E−02 B 35 LNU7_H4 0.73 1.61E−02 C 21 LNU45_H10 0.74 1.53E−02 C 12 LNU7_H4 0.75 1.18E−02 C 20 LNU76_H3 0.73 1.56E−02 C 9 LNU24_H2 0.76 1.07E−02 B 32 LNU74_H8 0.96 8.06E−03 C 18 LNU45_H11 0.76 1.07E−02 B 32 LNU74_H8 0.90 3.70E−02 C 18 LNU24_H2 0.86 1.39E−03 B 33 LNU76_H3 0.90 3.91E−02 C 18 LNU45_H11 0.86 1.39E−03 B 33 LNU45_H10 0.90 3.58E−02 C 18 LNU219_H1 0.87 1.13E−03 A 12 LNU45_H12 0.98 4.31E−03 C 18 LNU7_H4 0.82 3.80E−03 A 6 LNU256_H0 0.71 2.03E−02 C 11 LNU7_H4 0.78 7.67E−03 A 6 LNU76_H3 0.70 2.40E−02 C 11 LNU45_H10 0.89 5.71E−04 A 6 LNU46_H3 0.82 3.49E−03 C 6 LNU45_H9 0.73 1.76E−02 A 5 LNU45_H9 0.71 2.22E−02 C 5 LNU7_H4 0.74 1.45E−02 A 2 LNU45_H9 0.82 3.70E−03 C 2 LNU45_H10 0.86 1.29E−03 A 2 LNU7_H4 0.96 1.02E−02 B 35 LNU45_H9 0.80 5.07E−03 A 2 LNU219_H1 0.89 5.64E−04 C 8 LNU7_H4 0.70 2.32E−02 A 1 LNU74_H8 0.90 3.55E−02 B 35 LNU45_H10 0.89 5.60E−04 A 1 LNU45_H10 0.93 2.43E−02 B 35 LNU45_H9 0.74 1.49E−02 A 1 LNU45_H10 0.91 3.00E−02 B 35 LNU7_H4 0.98 2.32E−03 A 17 LNU46_H3 0.94 1.79E−02 B 35 LNU181_H0 0.95 1.14E−02 A 35 Table 7. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

Example 4 Production of Rice Transcriptom Using 44K Rice Oligonucleotide Micro-Array

In order to produce differential expression analysis of rice plants subjected to nitrogen limiting conditions compared to normal (non-limiting) nitrogen conditions, the present inventors have utilized a Rice oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 44,000 rice genes and transcripts.

Experimental Procedures

Rice plants grown under different nitrogen fertilization levels assessment—Five rice accessions were grown in 3 repetitive plots, each containing 10 plants, at a net house under semi-hydroponics conditions. Briefly, the growing protocol was as follows: Rice seeds were sown in trays filled with a mix of vermiculite and peat in a 1:1 ratio. Constant nitrogen limiting conditions were achieved by irrigating the plants with a solution containing 0.8 mM inorganic nitrogen in the form of KNO₃, supplemented with 1 mM KH₂PO₄, 1 mM MgSO₄, 3.6 mM K₂SO₄ and microelements, while normal nitrogen levels were achieved by applying a solution of 8 mM inorganic nitrogen also in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, and microelements.

Analyzed rice tissues—All 5 selected rice varieties were pooled in 1 batch per each treatment. Two tissues [leaves and roots] growing at two different nitrogen fertilization levels, 0.8 mM Nitrogen (nitrogen limiting conditions) or 8 mM Nitrogen (normal nitrogen conditions), were sampled and RNA was extracted as described above. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 8 below.

TABLE 8 Rice transcriptom experimental sets Expression Set Set ID Leaves at 0.8 mM Nitrogen fertilization A Leaves at 8 mM Nitrogen fertilization B Roots at 0.8 mM Nitrogen fertilization C Roots at 8 mM Nitrogen fertilization D Table 8.

Experimental Results

Gene up-regulation under reduced nitrogen fertilization levels indicates the involvement of the genes in NUE improvement. LNU116, LNU117, LNU118, LNU119, LNU120, LNU216, LNU217 and LNU276 were upregulated in Set ID C compared to their expression level in Set ID D. In addition, LNU116, LNU121, LNU176, LNU216, LNU217, LNU276 were upregulated in Set ID A compared to their expression level in Set ID B.

Example 5 Production of Arabidopsis Transcriptom and High Throughput Correlation Analysis of Yield, Biomass and/or Vigor Related Parameters Using 44K Arabidopsis Full Genome Oligonucleotide Micro-Array

To produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized an Arabidopsis thaliana oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 40,000 A. thaliana genes and transcripts designed based on data from the TIGR ATH1 v.5 database and Arabidopsis MPSS (University of Delaware) databases. To define correlations between the levels of RNA expression and yield, biomass components or vigor related parameters, various plant characteristics of 15 different Arabidopsis ecotypes were analyzed. Among them, nine ecotypes encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Analyzed Arabidopsis tissues—Five tissues at different developmental stages including root, leaf, flower at anthesis, seed at 5 days after flowering (DAF) and seed at 12 DAF, representing different plant characteristics, were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 9 below.

TABLE 9 Tissues used for Arabidopsis transcriptom expression sets Expression Set Set ID Root A Leaf B Flower C Seed 5 DAF D Seed 12 DAF E Table 9: Provided are the identification (ID) letters of each of the Arabidopsis expression sets (A-E). DAF = days after flowering.

Yield components and vigor related parameters assessment—Eight out of the nine Arabidopsis ecotypes were used in each of 5 repetitive blocks (named A, B, C, D and E), each containing 20 plants per plot. The plants were grown in a greenhouse at controlled conditions in 22° C., and the N:P:K fertilizer (20:20:20; weight ratios) [nitrogen (N), phosphorus (P) and potassium (K)] was added. During this time data was collected, documented and analyzed. Additional data was collected through the seedling stage of plants grown in a tissue culture in vertical grown transparent agar plates. Most of chosen parameters were analyzed by digital imaging.

Digital imaging in Tissue culture—A laboratory image acquisition system was used for capturing images of plantlets sawn in square agar plates. The image acquisition system consists of a digital reflex camera (Canon EOS 300D) attached to a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which included 4 light units (4×150 Watts light bulb) and located in a darkroom.

Digital imaging in Greenhouse—The image capturing process was repeated every 3-4 days starting at day 7 till day 30. The same camera attached to a 24 mm focal length lens (Canon EF series), placed in a custom made iron mount, was used for capturing images of larger plants sawn in white tubs in an environmental controlled greenhouse. The white tubs were square shape with measurements of 36×26.2 cm and 7.5 cm deep. During the capture process, the tubs were placed beneath the iron mount, while avoiding direct sun light and casting of shadows. This process was repeated every 3-4 days for up to 30 days.

An image analysis system was used, which consists of a personal desktop computer (Intel P43.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing program, which was developed at the U.S National Institutes of Health and is freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 6 Mega Pixels (3072×2048 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data was calculated, including leaf number, area, perimeter, length and width. On day 30, 3-4 representative plants were chosen from each plot of blocks A, B and C. The plants were dissected, each leaf was separated and was introduced between two glass trays, a photo of each plant was taken and the various parameters (such as leaf total area, laminar length etc.) were calculated from the images. The blade circularity was calculated as laminar width divided by laminar length.

Root analysis—During 17 days, the different ecotypes were grown in transparent agar plates. The plates were photographed every 3 days starting at day 7 in the photography room and the roots development was documented (see examples in FIGS. 3A-F). The growth rate of roots was calculated according to Formula V.

Relative growth rate of root coverage=Regression coefficient of root coverage along time course.  Formula V:

Vegetative growth rate analysis—was calculated according to Formula VI. The analysis was ended with the appearance of overlapping plants.

Relative vegetative growth rate area=Regression coefficient of vegetative area along time course.  Formula VI

For comparison between ecotypes the calculated rate was normalized using plant developmental stage as represented by the number of true leaves. In cases where plants with 8 leaves had been sampled twice (for example at day 10 and day 13), only the largest sample was chosen and added to the Anova comparison.

Seeds in siliques analysis—On day 70, 15-17 siliques were collected from each plot in blocks D and E. The chosen siliques were light brown color but still intact. The siliques were opened in the photography room and the seeds were scatter on a glass tray, a high resolution digital picture was taken for each plot. Using the images the number of seeds per silique was determined.

Seeds average weight—At the end of the experiment all seeds from plots of blocks A-C were collected. An average weight of 0.02 grams was measured from each sample, the seeds were scattered on a glass tray and a picture was taken. Using the digital analysis, the number of seeds in each sample was calculated.

Oil percentage in seeds—At the end of the experiment all seeds from plots of blocks A-C were collected. Columbia seeds from 3 plots were mixed grounded and then mounted onto the extraction chamber. 210 ml of n-Hexane (Cat No. 080951 Biolab Ltd.) were used as the solvent. The extraction was performed for 30 hours at medium heat 50° C. Once the extraction has ended the n-Hexane was evaporated using the evaporator at 35° C. and vacuum conditions. The process was repeated twice. The information gained from the Soxhlet extractor (Soxhlet, F. Die gewichtsanalytische Bestimmung des Milchfettes, Polytechnisches J. (Dingler's) 1879, 232, 461) was used to create a calibration curve for the Low Resonance NMR. The content of oil of all seed samples was determined using the Low Resonance NMR (MARAN Ultra-Oxford Instrument) and its MultiQuant software package.

Silique length analysis—On day 50 from sowing, 30 siliques from different plants in each plot were sampled in block A. The chosen siliques were green-yellow in color and were collected from the bottom parts of a grown plant's stem. A digital photograph was taken to determine silique's length.

Dry weight and seed yield—On day 80 from sowing, the plants from blocks A-C were harvested and left to dry at 30° C. in a drying chamber. The biomass and seed weight of each plot was separated, measured and divided by the number of plants. Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 30° C. in a drying chamber; Seed yield per plant=total seed weight per plant (gr).

Oil yield—The oil yield was calculated using Formula VII.

Seed Oil yield=Seed yield per plant (gr)*Oil % in seed.  Formula VII:

Harvest Index (seed)—The harvest index was calculated using Formula IV (described above).

Experimental Results

Nine different Arabidopsis ecotypes were grown and characterized for 18 parameters (named as vectors).

TABLE 10 Arabidopsis correlated parameters (vectors) Correlated parameter with Correlation ID Root length day 13 (cm) 1 Root length day 7 (cm) 2 Relative root growth (cm/day) day 13 3 Fresh weight per plant (gr) at bolting stage 4 Dry matter per plant (gr) 5 Vegetative growth rate (cm²/day) till 8 true leaves 6 Blade circularity 7 Lamina width (cm) 8 Lamina length (cm) 9 Total leaf area per plant (cm) 10 1000 Seed weight (gr) 11 Oil % per seed 12 Seeds per silique 13 Silique length (cm) 14 Seed yield per plant (gr) 15 Oil yield per plant (mg) 16 Harvest Index 17 Leaf width/length 18 Table 10. Provided are the Arabidopsis correlated parameters (correlation ID Nos. 1-18). Abbreviations: Cm = centimeter(s); gr = gram(s); mg = milligram(s).

The characterized values are summarized in Tables 11 and 12 below.

TABLE 11 Measured parameters in Arabidopsis ecotypes Ecotype 15 16 12 11 5 17 10 13 14 An-1 0.34 118.63 34.42 0.0203 0.64 0.53 46.86 45.44 1.06 Col-0 0.44 138.73 31.19 0.0230 1.27 0.35 109.89 53.47 1.26 Ct-1 0.59 224.06 38.05 0.0252 1.05 0.56 58.36 58.47 1.31 Cvi (N8580) 0.42 116.26 27.76 0.0344 1.28 0.33 56.80 35.27 1.47 Gr-6 0.61 218.27 35.49 0.0202 1.69 0.37 114.66 48.56 1.24 Kondara 0.43 142.11 32.91 0.0263 1.34 0.32 110.82 37.00 1.09 Ler-1 0.36 114.15 31.56 0.0205 0.81 0.45 88.49 39.38 1.18 Mt-0 0.62 190.06 30.79 0.0226 1.21 0.51 121.79 40.53 1.18 Shakdara 0.55 187.62 34.02 0.0235 1.35 0.41 93.04 25.53 1.00 Table 11. Provided are the values of each of the parameters measured in Arabidopsis ecotypes: 15 = Seed yield per plant (gram); 16 = oil yield per plant (mg); 12 = oil % per seed; 11 = 1000 seed weight (gr); 5 = dry matter per plant (gr); 17 = harvest index; 10 = total leaf area per plant (cm); 13 = seeds per silique; 14 = Silique length (cm).

TABLE 12 Additional measured parameters in Arabidopsis ecotypes Ecotype 6 3 2 1 4 9 8 18 7 An-1 0.313 0.631 0.937 4.419 1.510 2.767 1.385 0.353 0.509 Col-0 0.378 0.664 1.759 8.530 3.607 3.544 1.697 0.288 0.481 Ct-1 0.484 1.176 0.701 5.621 1.935 3.274 1.460 0.316 0.450 Cvi (N8580) 0.474 1.089 0.728 4.834 2.082 3.785 1.374 0.258 0.370 Gr-6 0.425 0.907 0.991 5.957 3.556 3.690 1.828 0.356 0.501 Kondara 0.645 0.774 1.163 6.372 4.338 4.597 1.650 0.273 0.376 Ler-1 0.430 0.606 1.284 5.649 3.467 3.877 1.510 0.305 0.394 Mt-0 0.384 0.701 1.414 7.060 3.479 3.717 1.817 0.335 0.491 Shakdara 0.471 0.782 1.251 7.041 3.710 4.149 1.668 0.307 0.409 Table 12. Provided are the values of each of the parameters measured in Arabidopsis ecotypes: 6 = Vegetative growth rate (cm²/day) until 8 true leaves; 3 = relative root growth (cm/day) (day 13); 2 = Root length day 7 (cm); 1 = Root length day 13 (cm); 4 = fresh weight per plant (gr) at bolting stage; 9. = Lamima length (cm); 8 = Lamina width (cm); 18 = Leaf width/length; 7 = Blade circularity.

Tables 13 and 14 provide the correlation analyses.

TABLE 13 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under normal or low nitrogen fertilization conditions across Arabidopsis accessions Gene Exp. Corr. Gene Exp. Corr. Name R P value set Set ID Name R P value set Set ID LNU1 0.74 3.45E−02 C 5 LNU186 0.83 1.14E−02 E 3 LNU1 0.83 2.02E−02 D 5 LNU186 0.71 4.90E−02 C 15 LNU1 0.81 2.58E−02 D 8 LNU186 0.79 2.05E−02 A 10 LNU1 0.77 4.08E−02 D 8 LNU186 0.72 4.50E−02 C 6 LNU1 0.97 4.59E−05 B 3 LNU187 0.81 1.38E−02 A 9 LNU1 0.88 4.21E−03 B 3 LNU187 0.77 2.40E−02 E 11 LNU1 0.73 3.79E−02 E 3 LNU206 0.76 2.89E−02 B 3 LNU1 0.92 1.10E−03 A 14 LNU207 0.83 1.08E−02 E 17 LNU1 0.72 4.38E−02 E 14 LNU210 0.74 3.52E−02 C 16 LNU123 0.87 4.82E−03 E 11 LNU210 0.89 2.97E−03 B 3 LNU123 0.82 1.22E−02 C 6 LNU210 0.74 3.61E−02 B 11 LNU124 0.73 3.90E−02 E 1 LNU211 0.92 1.22E−03 B 5 LNU124 0.71 4.96E−02 E 1 LNU211 0.73 4.00E−02 B 8 LNU125 0.79 2.07E−02 A 7 LNU212 0.85 7.78E−03 A 7 LNU125 0.72 4.19E−02 C 13 LNU212 0.75 3.23E−02 B 5 LNU125 0.85 7.49E−03 A 13 LNU212 0.72 4.52E−02 C 8 LNU126 0.80 3.09E−02 D 3 LNU212 0.93 9.64E−04 B 8 LNU127 0.82 2.36E−02 D 13 LNU212 0.77 2.59E−02 C 1 LNU127 0.81 1.53E−02 E 6 LNU212 0.77 2.54E−02 E 11 LNU129 0.74 3.42E−02 C 5 LNU212 0.77 2.63E−02 B 10 LNU129 0.85 1.49E−02 D 17 LNU213 0.72 4.28E−02 B 7 LNU129 0.79 2.04E−02 C 18 LNU213 0.86 6.08E−03 E 9 LNU129 0.73 3.85E−02 B 12 LNU213 0.75 3.39E−02 C 3 LNU129 0.77 2.60E−02 B 16 LNU213 0.88 3.77E−03 A 1 LNU129 0.86 5.89E−03 B 3 LNU213 0.81 1.40E−02 A 1 LNU129 0.82 1.25E−02 B 15 LNU213 0.85 1.66E−02 D 14 LNU129 0.78 2.34E−02 A 14 LNU213 0.83 1.14E−02 E 6 LNU132 0.82 1.26E−02 E 16 LNU214 0.73 4.08E−02 C 17 LNU132 0.94 6.45E−04 E 15 LNU215 0.86 6.04E−03 C 3 LNU133 0.80 3.06E−02 D 1 LNU215 0.77 2.68E−02 B 14 LNU133 0.91 4.56E−03 D 1 LNU215 0.78 2.15E−02 A 6 LNU134 0.78 2.26E−02 B 11 LNU218 0.81 1.53E−02 A 12 LNU134 0.75 3.13E−02 B 14 LNU218 0.73 3.81E−02 E 6 LNU135 0.76 4.61E−02 D 1 LNU219 0.71 4.78E−02 B 12 LNU135 0.84 8.88E−03 B 6 LNU219 0.78 2.20E−02 B 16 LNU135 0.74 3.45E−02 E 6 LNU219 0.71 4.98E−02 B 3 LNU136 0.82 1.18E−02 E 5 LNU225 0.75 3.36E−02 B 7 LNU136 0.79 1.85E−02 C 4 LNU225 0.81 1.58E−02 C 18 LNU136 0.76 2.70E−02 C 8 LNU225 0.90 2.55E−03 B 18 LNU136 0.71 4.69E−02 A 14 LNU225 0.83 1.03E−02 A 18 LNU136 0.82 1.18E−02 C 10 LNU225 0.75 3.27E−02 E 18 LNU14 0.72 4.41E−02 A 1 LNU23 0.90 2.05E−03 C 11 LNU14 0.86 6.57E−03 E 11 LNU23 0.91 1.72E−03 B 11 LNU14 0.75 3.20E−02 B 15 LNU234 0.71 4.90E−02 E 9 LNU14 0.75 3.11E−02 E 14 LNU234 0.75 3.19E−02 E 6 LNU140 0.71 4.67E−02 C 15 LNU24 0.73 4.05E−02 A 3 LNU15 0.75 3.37E−02 B 12 LNU247 0.81 1.51E−02 C 13 LNU15 0.95 2.59E−04 B 16 LNU249 0.74 3.73E−02 B 17 LNU15 0.91 1.48E−03 B 15 LNU249 0.77 4.42E−02 D 17 LNU170 0.85 7.15E−03 C 12 LNU249 0.75 3.35E−02 E 6 LNU170 0.76 3.00E−02 A 12 LNU250 0.74 3.45E−02 C 7 LNU170 0.75 3.30E−02 C 16 LNU250 0.74 3.67E−02 E 18 LNU170 0.92 1.24E−03 A 16 LNU250 0.71 4.84E−02 E 12 LNU170 0.79 1.86E−02 E 16 LNU250 0.78 2.20E−02 A 11 LNU170 0.76 2.96E−02 E 3 LNU251 0.79 3.56E−02 D 7 LNU170 0.87 4.80E−03 A 15 LNU251 0.85 8.12E−03 B 13 LNU170 0.73 3.82E−02 E 15 LNU251 0.73 3.88E−02 A 13 LNU175 0.81 1.49E−02 A 17 LNU251 0.78 2.12E−02 A 14 LNU175 0.76 4.68E−02 D 18 LNU254 0.83 9.96E−03 B 5 LNU177 0.90 5.47E−03 D 5 LNU254 0.78 2.20E−02 B 8 LNU177 0.96 4.41E−04 D 8 LNU255 0.89 2.76E−03 A 1 LNU177 0.71 4.99E−02 B 1 LNU256 0.79 1.85E−02 E 3 LNU177 0.90 5.34E−03 D 10 LNU256 0.89 2.98E−03 E 11 LNU178 0.82 1.26E−02 C 1 LNU256 0.73 4.18E−02 B 13 LNU178 0.71 4.72E−02 E 13 LNU256 0.78 2.10E−02 E 14 LNU179 0.83 1.14E−02 E 3 LNU258 0.75 3.08E−02 C 12 LNU179 0.73 4.13E−02 B 11 LNU258 0.81 1.50E−02 E 16 LNU179 0.78 2.32E−02 E 14 LNU258 0.83 9.93E−03 E 15 LNU179 0.84 9.15E−03 E 6 LNU258 0.81 1.48E−02 A 13 LNU181 0.75 3.03E−02 B 7 LNU260 0.85 1.52E−02 D 5 LNU181 0.77 2.41E−02 A 14 LNU260 0.79 3.43E−02 D 8 LNU183 0.80 1.68E−02 E 8 LNU260 0.74 3.40E−02 C 1 LNU183 0.77 2.68E−02 E 10 LNU260 0.73 3.78E−02 C 1 LNU184 0.73 3.79E−02 A 1 LNU260 0.83 1.10E−02 E 1 LNU185 0.83 2.23E−02 D 16 LNU261 0.73 3.90E−02 C 9 LNU185 0.77 4.27E−02 D 3 LNU261 0.76 2.98E−02 B 16 LNU185 0.92 1.20E−03 E 11 LNU261 0.85 6.86E−03 A 1 LNU185 0.75 3.22E−02 B 15 LNU261 0.82 2.29E−02 D 11 LNU185 0.82 2.27E−02 D 15 LNU261 0.94 1.95E−03 D 6 LNU186 0.79 1.88E−02 C 5 LNU262 0.77 4.15E−02 D 7 LNU186 0.81 1.57E−02 A 5 LNU262 0.71 4.97E−02 B 5 LNU186 0.80 1.59E−02 E 5 LNU262 0.71 4.67E−02 E 8 LNU186 0.73 4.09E−02 C 4 LNU262 0.87 5.11E−03 E 16 LNU186 0.80 1.77E−02 A 4 LNU262 0.94 4.36E−04 E 15 LNU186 0.74 3.39E−02 C 9 LNU8 0.74 3.71E−02 B 3 LNU186 0.75 3.24E−02 A 9 LNU8 0.84 8.67E−03 A 3 LNU186 0.73 3.92E−02 C 8 LNU8 0.72 4.37E−02 E 1 LNU186 0.82 1.17E−02 A 8 LNU8 0.72 4.38E−02 A 11 Table 13. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

TABLE 14 Correlation between the expression level of selected LNU orthologs genes of some embodiments of the invention in various tissues and the phenotypic performance under normal or low nitrogen fertilization conditions across Arabidopsis accessions Gene Exp. Correl. Gene Exp. Correl. Name R P value Set Set ID Name R P value Set Set ID LNU24_H1 0.75 3.13E−02 C 7 LNU45_H12 0.76 2.91E−02 A 14 LNU46_H3 0.75 3.24E−02 C 9 LNU24_H1 0.80 1.77E−02 A 6 LNU181_H0 0.71 4.84E−02 C 3 LNU256_H0 0.76 2.90E−02 A 6 LNU46_H5 0.87 4.72E−03 C 3 LNU46_H3 0.72 4.43E−02 E 5 LNU76_H3 0.76 2.75E−02 C 2 LNU219_H1 0.77 2.49E−02 E 8 LNU181_H0 0.75 3.05E−02 B 7 LNU219_H1 0.80 1.69E−02 E 1 LNU256_H0 0.84 9.66E−03 B 5 LNU219_H1 0.81 1.39E−02 E 2 LNU46_H4 0.73 3.78E−02 B 8 LNU24_H0 0.86 5.99E−03 E 11 LNU45_H9 0.73 4.02E−02 B 16 LNU74_H8 0.88 3.96E−03 E 11 LNU46_H4 0.76 2.91E−02 B 1 LNU46_H4 0.76 2.94E−02 E 15 LNU24_H0 0.74 3.72E−02 B 11 LNU181_H0 0.84 9.43E−03 E 14 LNU45_H9 0.77 2.55E−02 B 15 LNU24_H0 0.83 1.09E−02 E 14 LNU181_H0 0.85 6.93E−03 B 13 LNU74_H8 0.77 2.54E−02 E 14 LNU24_H0 0.73 3.87E−02 B 14 LNU74_H9 0.76 2.93E−02 E 14 LNU76_H3 0.89 3.16E−03 B 14 LNU46_H3 0.71 4.67E−02 E 14 LNU46_H3 0.73 3.97E−02 B 6 LNU219_H1 0.81 1.43E−02 E 10 LNU256_H0 0.77 2.56E−02 A 5 LNU76_H3 0.88 9.64E−03 D 5 LNU24_H1 0.71 4.63E−02 A 9 LNU45_H10 0.89 6.71E−03 D 5 LNU256_H0 0.88 3.57E−03 A 9 LNU76_H3 0.87 1.09E−02 D 8 LNU46_H4 0.85 8.11E−03 A 3 LNU45_H10 0.95 9.46E−04 D 8 LNU24_H1 0.74 3.45E−02 A 11 LNU46_H3 0.77 4.26E−02 D 8 LNU7_H4 0.71 4.64E−02 A 11 LNU45_H9 0.88 9.11E−03 D 2 LNU181_H0 0.75 3.26E−02 A 14 LNU74_H9 0.85 1.63E−02 D 11 LNU7_H5 0.80 1.74E−02 A 14 LNU45_H10 0.83 2.05E−02 D 10 LNU45_H12 0.76 4.62E−02 D 6 Table 14. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

Example 6 Production of Barley Transcriptom and High Throughput Correlation Analysis Using 44K Barley Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a Barley oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 47,500 Barley genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 25 different Barley accessions were analyzed. Among them, 13 accessions encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Analyzed Barley tissues—Five tissues at different developmental stages [meristem, flower, booting spike, stem, flag leaf], representing different plant characteristics, were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 15 below.

TABLE 15 Barley transcriptom expression sets Expression Set Set ID Meristem A Flower B Booting spike C Stem D Flag leaf E Table 15

Barley yield components and vigor related parameters assessment—25 Barley accessions in 4 repetitive blocks (named A, B, C, and D), each containing 4 plants per plot were grown at net house. Plants were phenotyped on a daily basis following the standard descriptor of barley (Table 16, below). Harvest was conducted while 50% of the spikes were dry to avoid spontaneous release of the seeds. Plants were separated to the vegetative part and spikes, of them, 5 spikes were threshed (grains were separated from the glumes) for additional grain analysis such as size measurement, grain count per spike and grain yield per spike. All material was oven dried and the seeds were threshed manually from the spikes prior to measurement of the seed characteristics (weight and size) using scanning and image analysis. The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

TABLE 16 Barley standard descriptors Trait Parameter Range Description Growth habit Scoring 1-9 Prostrate (1) or Erect (9) Hairiness of basal leaves Scoring P (Presence)/ Absence (1) or Presence (2) A (Absence) Stem pigmentation Scoring 1-5 Green (1), Basal only or Half or more (5) Days to Flowering Days Days from sowing to emergence of awns Plant height Centimeter (cm) Height from ground level to top of the longest spike excluding awns Spikes per plant Number Terminal Counting Spike length Centimeter (cm) Terminal Counting 5 spikes per plant Grains per spike Number Terminal Counting 5 spikes per plant Vegetative dry weight Gram Oven-dried for 48 hours at 70° C. Spikes dry weight Gram Oven-dried for 48 hours at 30° C. Table 16.

Grains per spike—At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D are collected. The total number of grains from 5 spikes that were manually threshed was counted. The average grain per spike is calculated by dividing the total grain number by the number of spikes.

Grain average size (cm)—At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D are collected. The total grains from 5 spikes that were manually threshed were scanned and images were analyzed using the digital imaging system. Grain scanning was done using Brother scanner (model DCP-135), at the 200 dpi resolution and analyzed with Image J software. The average grain size was calculated by dividing the total grain size by the total grain number.

Grain average weight (mgr)—At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D are collected. The total grains from 5 spikes that were manually threshed were counted and weight. The average weight was calculated by dividing the total weight by the total grain number.

Grain yield per spike (gr)—At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D are collected. The total grains from 5 spikes that were manually threshed were weight. The grain yield was calculated by dividing the total weight by the spike number.

Spike length analysis—At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D are collected. The five chosen spikes per plant were measured using measuring tape excluding the awns.

Spike number analysis—At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D are collected. The spikes per plant were counted.

Growth habit scoring—At the growth stage 10 (booting), each of the plants was scored for its growth habit nature. The scale that was used was 1 for prostate nature till 9 for erect.

Hairiness of basal leaves—At the growth stage 5 (leaf sheath strongly erect; end of tillering), each of the plants was scored for its hairiness nature of the leaf before the last. The scale that was used was 1 for prostate nature till 9 for erect.

Plant height—At the harvest stage (50% of spikes were dry) each of the plants was measured for its height using measuring tape. Height was measured from ground level to top of the longest spike excluding awns.

Days to flowering—Each of the plants was monitored for flowering date. Days of flowering was calculated from sowing date till flowering date.

Stem pigmentation—At the growth stage 10 (booting), each of the plants was scored for its stem color. The scale that was used was 1 for green till 5 for full purple.

Vegetative dry weight and spike yield—At the end of the experiment (50% of the spikes were dry) all spikes and vegetative material from plots within blocks A-D are collected. The biomass and spikes weight of each plot was separated, measured and divided by the number of plants.

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours;

Spike yield per plant=total spike weight per plant (gr) after drying at 30° C. in oven for 48 hours.

Harvest Index (for barley)—The harvest index is calculated using Formula VIII.

Harvest Index=Average spike dry weight per plant/(Average vegetative dry weight per plant+Average spike dry weight per plant)  Formula VIII:

TABLE 17 Barley correlated parameters (vectors) Correlated parameter with (units) Correlation Id Grains per spike (numbers) 1 Grains size (mm²) 2 Grain weight (miligrams) 3 Grain Yield per spike (gr/spike) 4 Spike length (cm) 5 Spikes per plant (numbers) 6 Growth habit (scores 1-9) 7 Hairiness of basal leaves (scoring 1-2) 8 Plant height (cm) 9 Days to flowering (days) 10 Stem pigmentation (scoring 1-5) 11 Vegetative dry weight (gram) 12 Harvest Index (ratio) 13 Table 17.

Experimental Results

13 different Barley accessions were grown and characterized for 13 parameters as described above. The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 18 and 19 below. Subsequent correlation analysis between the various transcriptom sets (Table 15) and the average parameters, was conducted (Tables 20 and 21). Follow, results were integrated to the database.

TABLE 18 Measured parameters of correlation Ids in Barley accessions Parameter Accession 6 10 3 5 2 1 7 Amatzya 48.85 62.40 35.05 12.04 0.27 20.23 2.60 Ashqelon 48.27 64.08 28.06 10.93 0.23 17.98 2.00 Canada park 37.42 65.15 28.76 11.83 0.24 17.27 1.92 Havarim stream 61.92 58.92 17.87 9.90 0.17 17.73 3.17 Jordan est 33.27 63.00 41.22 11.68 0.29 14.47 4.33 Klil 41.69 70.54 29.73 11.53 0.28 16.78 2.69 Maale Efraim ND 52.80 25.22 8.86 0.22 13.47 3.60 Mt Arbel 40.63 60.88 34.99 11.22 0.28 14.07 3.50 Mt Harif 62.00 58.10 20.58 11.11 0.19 21.54 3.00 Neomi 49.33 53.00 27.50 8.58 0.22 12.10 3.67 Neot Kdumim 50.60 60.40 37.13 10.18 0.27 14.36 2.47 Oren canyon 43.09 64.58 29.56 10.51 0.27 15.28 3.50 Yeruham 51.40 56.00 19.58 9.80 0.18 17.07 3.00 Table 18. Provided are the values of each of the parameters measured in Barley accessions according to the following correlation identifications (Correlation Ids): 6 = Spikes per plant; 10 = Days to flowering; 3 = Grain weight; 5 = Spike length; 2 = Grains Size; 1 = Grains per spike; 7 = Growth habit.

TABLE 19 Barley accessions, additional measured parameters Parameter Accession 8 9 4 11 12 13 Amatzya 1.53 134.27 3.56 1.13 78.87 0.45 Ashqelon 1.33 130.50 2.54 2.50 66.14 0.42 Canada park 1.69 138.77 2.58 1.69 68.49 0.40 Havarim stream 1.08 114.58 1.57 1.75 53.39 0.44 Jordan est 1.42 127.75 3.03 2.33 68.30 0.43 Klil 1.69 129.38 2.52 2.31 74.17 0.40 Maale Efraim 1.30 103.89 1.55 1.70 35.35 0.52 Mt Arbel 1.19 121.63 2.62 2.19 58.33 0.48 Mt Harif 1.00 126.80 2.30 2.30 62.23 0.44 Neomi 1.17 99.83 1.68 1.83 38.32 0.49 Neot Kdumim 1.60 121.40 2.68 3.07 68.31 0.45 Oren canyon 1.08 118.42 2.35 1.58 56.15 ND Yeruham 1.17 117.17 1.67 2.17 42.68 ND Table 19. Provided are the values of each of the parameters measured in Barley accessions according to the following correlation identifications (Correlation Ids): 8 = Hairiness of basal leaves; 9 = Plant height; 4 = Grain yield per spike; 11 = Stem pigmentation; 12 = Vegetative dry weight; 13 = Harvest Index.

TABLE 20 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under normal fertilization conditions across barley accessions Gene Exp. Corr. Gene Exp. Corr. Name R P value Set ID Set ID Name R P value Set ID Set ID LNU72 0.77 6.01E−03 A 2 LNU28 0.79 1.14E−02 C 3 LNU72 0.75 7.97E−03 A 3 LNU28 0.78 4.43E−03 C 2 LNU72 0.75 2.03E−02 A 3 LNU28 0.78 4.67E−03 C 3 LNU72 0.74 2.13E−02 A 2 LNU172 0.81 1.56E−02 C 7 LNU240 0.73 1.15E−02 C 6 LNU228 0.86 3.07E−03 A 3 LNU240 0.70 3.44E−02 C 6 LNU228 0.86 7.60E−04 A 3 LNU244 0.72 4.57E−02 C 7 LNU228 0.81 7.47E−03 A 2 LNU27 0.81 7.70E−03 A 1 LNU228 0.79 1.99E−02 C 6 LNU27 0.78 1.24E−02 A 9 LNU228 0.79 3.90E−03 C 6 LNU27 0.76 1.72E−02 A 12 LNU228 0.75 7.78E−03 A 2 LNU27 0.72 1.17E−02 A 12 LNU224 0.85 1.53E−02 C 6 LNU28 0.80 1.02E−02 C 2 Table 20. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

TABLE 21 Correlation between the expression level of selected LNU orthologs genes of some embodiments of the invention in various tissues and the phenotypic performance under normal fertilization conditions across barley accessions Gene Exp. Correl. Gene Exp. Correl. Name R P value Set Set ID Name R P value Set Set ID LNU52_H0 0.91 5.92E−04 C 3 LNU89_H0 0.73 3.99E−02 A 8 LNU52_H0 0.91 9.60E−05 C 3 LNU89_H0 0.73 3.99E−02 A 8 LNU89_H0 0.76 2.80E−02 C 3 LNU76_H11 0.71 3.36E−02 A 8 LNU89_H0 0.76 2.80E−02 C 3 LNU76_H11 0.71 3.36E−02 A 8 LNU85_H0 0.74 2.27E−02 C 3 LNU2_H0 0.81 8.66E−03 A 9 LNU85_H0 0.74 2.27E−02 C 3 LNU2_H0 0.72 1.31E−02 A 9 LNU2_H0 0.75 1.94E−02 C 1 LNU2_H0 0.81 8.66E−03 A 9 LNU2_H0 0.75 1.94E−02 C 1 LNU2_H0 0.72 1.31E−02 A 9 LNU2_H0 0.73 2.65E−02 C 1 LNU2_H0 0.88 1.59E−03 A 5 LNU2_H0 0.72 1.30E−02 C 1 LNU2_H0 0.75 7.76E−03 A 5 LNU2_H0 0.73 2.65E−02 C 1 LNU2_H0 0.88 1.59E−03 A 5 LNU2_H0 0.72 1.30E−02 C 1 LNU2_H0 0.75 7.76E−03 A 5 LNU268_H0 0.79 4.16E−03 C 1 LNU69_H0 0.79 2.01E−02 A 6 LNU268_H0 0.78 1.27E−02 C 1 LNU69_H0 0.79 2.01E−02 A 6 LNU52_H0 0.93 2.81E−04 C 2 LNU45_H52 0.76 4.62E−02 A 6 LNU52_H0 0.92 5.39E−05 C 2 LNU45_H52 0.76 4.62E−02 A 6 LNU85_H0 0.73 2.63E−02 B 2 LNU51_H0 0.86 6.78E−03 A 6 LNU85_H0 0.73 2.63E−02 B 2 LNU51_H0 0.71 1.41E−02 A 6 LNU89_H0 0.81 1.44E−02 B 2 LNU51_H0 0.86 6.78E−03 A 6 LNU89_H0 0.81 1.44E−02 B 2 LNU51_H0 0.71 1.41E−02 A 6 LNU85_H0 0.74 2.21E−02 B 2 LNU60_H0 0.72 1.31E−02 A 6 LNU85_H0 0.71 1.51E−02 B 2 LNU60_H0 0.72 1.31E−02 A 6 LNU85_H0 0.74 2.21E−02 B 2 LNU67_H0 0.88 3.84E−03 A 6 LNU85_H0 0.71 1.51E−02 B 2 LNU67_H0 0.72 1.17E−02 A 6 LNU74_H31 0.72 3.00E−02 B 7 LNU67_H0 0.88 3.84E−03 A 6 LNU74_H31 0.72 3.00E−02 B 7 LNU67_H0 0.72 1.17E−02 A 6 LNU85_H0 0.83 5.97E−03 B 8 LNU46_H7 0.89 3.10E−03 A 6 LNU85_H0 0.81 2.45E−03 B 8 LNU46_H7 0.83 1.45E−03 A 6 LNU85_H0 0.83 5.97E−03 A 8 LNU46_H7 0.89 3.10E−03 A 6 LNU85_H0 0.81 2.45E−03 A 8 LNU46_H7 0.83 1.45E−03 A 6 LNU52_H1 0.71 4.86E−02 A 8 LNU35_H0 0.87 4.90E−03 A 6 LNU52_H1 0.70 2.31E−02 A 8 LNU35_H0 0.85 8.62E−04 A 6 LNU52_H1 0.71 4.86E−02 A 8 LNU35_H0 0.87 4.90E−03 A 6 LNU52_H1 0.70 2.31E−02 A 8 LNU35_H0 0.85 8.62E−04 A 6 Table 21. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

Example 7 Production of Sorghum Transcriptom and High Throughput Correlation Analysis with Yield, Nue, and Abst Related Parameters Measured in Fields Using 44K Sorguhm Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a sorghum oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 44,000 sorghum genes and transcripts. In order to define correlations between the levels of RNA expression with ABST, yield and NUE components or vigor related parameters, various plant characteristics of 17 different sorghum hybrids were analyzed. Among them, 10 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Correlation of Sorghum Varieties Across Ecotypes Grown Under Low Nitrogen, Regular Growth and Severe Drought Conditions

Experimental Procedures

17 Sorghum varieties were grown in 3 repetitive plots, in field. Briefly, the growing protocol was as follows:

1. Regular growth conditions: sorghum plants were grown in the field using commercial fertilization and irrigation protocols.

2. Low Nitrogen fertilization conditions: sorghum plants were fertilized with 50% less amount of nitrogen in the field than the amount of nitrogen applied in the regular growth treatment. All the fertilizer was applied before flowering.

3. Drought stress: sorghum seeds were sown in soil and grown under normal condition until around 35 days from sowing, around V8. At this point, irrigation was stopped, and severe drought stress was developed. In order to define correlations between the levels of RNA expression with NUE, drought, and yield components or vigor related parameters, the 17 different sorghum varieties were analyzed. Among them, 10 varieties encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Analyzed Sorghum tissues—All 10 selected Sorghum hybrids were sample per each treatment. Plant tissues [Flag leaf, Flower meristem and Flower] growing under low nitrogen, severe drought stress and plants grown under Normal conditions were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 22 below.

TABLE 22 Sorghum transcriptom expression sets in field experiments Expression Set Set ID Sorghum field/Normal/flower meristem A Sorghum field/Normal/flower B Sorghum field/Normal/leaf C Sorghum field/Low N/flower meristem D Sorghum field/Low N/flower E Sorghum field/Low N/leaf F Sorghum field/Drought/flower meristem G Sorghum field/Drought/flower H Sorghum field/Drought/leaf I Table 22: Provided are the sorghum transcriptom expression sets.

The following parameters were collected using digital imaging system:

Average Grain Area (cm²)—At the end of the growing period the grains were separated from the Plant ‘Head’. A sample of −200 grains were weight, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Average Grain Length (cm)—At the end of the growing period the grains were separated from the Plant ‘Head’. A sample of −200 grains were weight, photographed and images were processed using the below described image processing system. The sum of grain lengths (longest axis) was measured from those images and was divided by the number of grains.

Head Average Area (cm²) At the end of the growing period 5 ‘Heads’ were, photographed and images were processed using the below described image processing system. The ‘Head’ area was measured from those images and was divided by the number of ‘Heads’.

Head Average Length (cm) At the end of the growing period 5 ‘Heads’ were, photographed and images were processed using the below described image processing system. The ‘Head’ length (longest axis) was measured from those images and was divided by the number of ‘Heads’.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 5 plants per plot or by measuring the parameter across all the plants within the plot.

Total Seed Weight per Head (gr.)—At the end of the experiment (plant ‘Heads’) heads from plots within blocks A-C were collected. 5 heads were separately threshed and grains were weighted, all additional heads were threshed together and weighted as well. The average grain weight per head was calculated by dividing the total grain weight by number of total heads per plot (based on plot). In case of 5 heads, the total grains weight of 5 heads was divided by 5.

FW Head per Plant gr—At the end of the experiment (when heads were harvested) total and 5 selected heads per plots within blocks A-C were collected separately. The heads (total and 5) were weighted (gr.) separately and the average fresh weight per plant was calculated for total (FW Head/Plant gr based on plot) and for 5 (FW Head/Plant gr based on 5 plants).

Plant height—Plants were characterized for height during growing period at 5 time points. In each measure, plants were measured for their height using a measuring tape. Height was measured from ground level to top of the longest leaf.

Plant leaf number—Plants were characterized for leaf number during growing period at 5 time points. In each measure, plants were measured for their leaf number by counting all the leaves of 3 selected plants per plot.

Relative Growth Rate was calculated using Formulas IX and X.

Relative growth rate of plant height=Regression coefficient of plant height along time course.  Formula IX

Relative growth rate of plant leaf number=Regression coefficient of plant leaf number along time course.  Formula X

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Vegetative dry weight and Heads—At the end of the experiment (when Inflorescence were dry) all Inflorescence and vegetative material from plots within blocks A-C were collected. The biomass and Heads weight of each plot was separated, measured and divided by the number of Heads.

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours;

Harvest Index (HI) (Sorghum)—The harvest index was calculated using Formula XI.

Harvest Index=Average grain dry weight per Head/(Average vegetative dry weight per Head+Average Head dry weight)  Formula XI:

FW Heads/(FW Heads+FW Plants)—The total fresh weight of heads and their respective plant biomass were measured at the harvest day. The heads weight was divided by the sum of weights of heads and plants.

Experimental Results

17 different sorghum hybrids were grown and characterized for different parameters: The average for each of the measured parameter was calculated using the JMP software (Tables 23-29) and a subsequent correlation analysis was performed (Tables 30-31). Results were then integrated to the database.

TABLE 23 Sorghum correlated parameters (vectors) Correlation set Correlation ID Leaf SPAD 64 Days Post Sowing-normal [SPAD unit] 1 RGR of Leaf Num-normal 2 Total Seed Weight/Head gr based on plot-normal [gr] 3 Head Average Area cm2-normal [cm2] 4 Head Average Length cm-normal [cm] 5 Average Seed Area cm2-normal [cm2] 6 Average Seed Length cm-normal [cm] 7 FW Head/Plant gr based on plot-normal [gr] 8 FW per Plant gr based on plot-normal [gr] 9 Final Plant Height cm-normal [cm] 10 HI-normal 11 FW Heads/(FW Heads + FW Plants) all plot-normal [gr] 12 RGR of Plant Height-normal 13 FW-Inflorescence per Plant Normal [gr] 14 DW per Plant Normal [gr] 15 DW-5 Inflorescence Normal [gr] 16 Seed Yield Normal [gr] 17 Leaf No 2 Normal [number] 18 Plant Height 2 Normal [cm] 19 SPAD 2 Normal [SPAD unit] 20 Leaf No 3 Normal [number] 21 Plant Height 3 Normal [cm] 22 Leaf No 4 Normal [number] 23 Plant Height 4 Normal [cm] 24 Leaf No 5 Normal [number] 25 Leaf No 6 Normal [number] 26 Plant Height 6 Normal [cm] 27 Plant Height 5 Low-N [cm] 28 FW-Inflorescence per Plant Low-N 29 DW per Plant Low-N 30 Seed per Plant Low-N 31 Seed yield Low-N [gr] 32 Leaf No 2 Low-N [number] 33 Plant Height 2 Low-N [cm] 34 SPAD 2 Low-N 35 Leaf No 3 Low-N [number] 36 Plant Height 3 Low-N [cm] 37 Leaf No 5 Low-N [number] 38 RGR of Leaf Num-NUE 39 Total Seed Yield per Head gr based on plot-NUE 40 Head Average Area cm2-NUE [cm2] 41 Head Average Perimeter cm-NUE [cm] 42 Head Average Length cm-NUE [cm] 43 Head Average Width cm-NUE [cm] 44 Average Seed Area cm2-NUE [cm2] 45 Average Seed Length cm-NUE [cm] 46 FW Head per Plant gr based on plot-NUE [gr] 47 FW per Plant gr based on plot-NUE [gr] 48 Leaf SPAD 64 Days Post Sowing-NUE [SPAD unit] 49 HI-NUE 50 FW Heads/(FW Heads + FW Plants) all plot-NUE [gr] 51 FW-Inflorescence per Plant Drought [gr] 52 Dw per Plant Drought [gr] 53 Seed per Plant Drought [gr] 54 DW-5 Inflorescence Drought [gr] 55 Seed Yield Drought [gr] 56 Seed Yield (5 heads) gr Drought 57 Leaf No 2 Drought [number] 58 Plant Height 2 Drought [cm] 59 SPAD 2 Drought [SPAD unit] 60 Leaf No 3 Drought [number] 61 Plant Height 3 Drought [cm] 62 Leaf No 4 Drought [number] 63 Plant Height 4 Drought [cm] 64 Leaf No 5 Drought [number] 65 Plant Height 5 Drought [cm] 66 Leaf No 6 Drought [number] 67 Plant Height 6 Drought [cm] 68 Average Seed Area cm2-Drought [cm2] 69 Average Seed Length cm-Drought [cm] 70 Total Seed Yield per Head gr based on plot-Drought [gr] 71 Head Average Area cm2-Drought [cm2] 72 Head Average Perimeter cm-Drought [cm] 73 Head Average Length cm-Drought [cm] 74 Head Average Width cm-Drought [cm] 75 HI-Drought 76 RGR of Leaf_Num-Drought 77 Table 23. Provided are the Sorghum correlated parameters (vectors). “gr.” = grams; “SPAD” = chlorophyll levels; “FW” = Plant Fresh weight; “DW” = Plant Dry weight; “normal” = standard growth conditions; “RGR” = relative growth rate.

TABLE 24 Measured parameters in Sorghum accessions under normal conditions Seed ID 1 2 3 4 5 6 7 8 9 10 11 12 13 14 20 43 0.10 31 120 26 0.11 0.39 175 163 95 201 0.51 1.89 0.18 21 26 168 27 0.11 0.40 223 213 79 127 0.51 1.62 0.68 22 43 0.21 19 85 21 0.13 0.45 56 335 198 52 0.12 3.42 0.06 24 45 0.19 38 157 27 0.13 0.45 112 313 234 122 0.26 2.42 0.11 25 46 0.19 189 55 0.12 3.12 0.07 26 42 0.16 195 94 0.18 3.32 0.09 27 45 0.20 48 169 31 0.11 0.40 126 151 117 327 0.46 2.18 0.13 28 45 0.17 31 109 23 0.11 0.41 108 138 93 231 0.43 2.19 0.11 29 43 0.18 40 135 26 0.10 0.38 124 168 113 241 0.43 2.57 0.12 30 46 38 169 29 0.12 0.42 103 129 98 304 0.44 2.05 0.10 31 45 32 156 28 0.12 0.43 82 98 98 336 0.46 2.07 0.08 32 45 0.18 33 112 23 0.11 0.40 78 99 100 350 0.45 2.55 0.08 33 47 0.12 33 155 28 0.12 0.41 91 112 106 293 0.45 2.33 0.09 34 44 0.21 52 172 30 0.11 0.40 150 157 151 411 0.51 3.04 0.15 35 45 0.19 36 169 31 0.11 0.40 109 131 117 285 0.46 2.33 0.11 36 45 0.15 38 163 27 0.11 0.40 108 136 124 283 0.44 2.52 0.11 37 43 0.24 42 170 29 0.11 0.39 131 209 126 204 0.39 2.81 0.13 Table 24: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 25 Additional measured parameters in Sorghum accessions under normal growth conditions Seed ID 15 16 17 18 19 20 21 22 23 24 25 26 27 20 0.16 0.04 1.15 5.31 10.6 43 5.44 24.5 6.73 37.3 6.75 6.73 37.3 21 0.25 0.06 0.48 6.08 8 40.7 6.38 19.9 8.44 47.8 8.38 8.44 47.8 22 0.34 0.03 1.22 6 16 43.3 6.56 31.1 7.25 40.1 9.81 7.25 40.1 24 0.31 0.03 2.61 5.44 11.9 44.7 5.75 24.5 7.88 45.9 8.81 7.88 45.9 25 0.46 0.07 0.99 5.38 14.2 45.8 5.12 27.2 8.12 41.4 8.69 8.12 41.4 26 0.36 0.05 2.67 6.31 15.3 41.6 6.31 27.2 9.12 44.9 9.5 9.12 44.9 27 0.15 0.05 3.59 6.12 15.7 45.2 6.19 31.2 7.5 42.1 9.19 7.5 42.1 28 0.14 0.03 2.12 6.06 15.9 45.1 6.06 30.2 8.25 41 6.69 8.25 41 29 0.17 0.05 2.50 6.12 14.6 43 5.62 26.2 7 42.5 9 7 42.1 30 0.13 0.04 2.78 6.44 18.4 45.6 5.94 31.9 6.75 41.9 6.75 6.75 41.9 31 0.10 0.02 3.16 7 18.1 44.8 6 32.2 8.06 43.4 6.38 8.06 43.4 32 0.10 0.04 3.41 6.31 17.2 45.3 6.38 29.8 6.94 39.8 7.81 6.94 39.8 33 0.11 0.05 2.94 6.25 14.9 46.5 6.31 28.1 7.94 40.6 7.88 7.94 40.6 34 0.16 0.05 2.80 6.25 13.5 44 5.94 27 8.06 44.4 9.94 8.06 44.4 35 0.13 0.04 2.90 5.62 14.6 45.1 5.94 29.2 7.56 43.2 8.69 7.56 43.2 36 0.14 0.04 3.40 6.38 16.4 45.1 5.75 27.8 7.94 41 8.56 7.94 41 37 0.21 0.06 3.16 5.88 17.3 43.1 6.56 31.6 10.3 Table 25: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 26 Measured parameters in Sorghum accessions under Low nitrogen conditions Seed Id 28 29 30 31 32 33 34 35 36 37 38 39 40 20 52.2 0.155 0.208 0.0221 0.563 5.47 12 40.6 6 27.8 7.67 25.9 21 40.6 0.122 0.138 0.0168 0.347 5.58 9.58 40.9 6.33 22.7 8.5 0.185 30.6 22 67.4 0.131 0.255 0.00919 0.68 5.58 13.9 45 5.83 27.8 8.83 0.186 19.4 24 66.2 0.241 0.402 0.104 0.94 5.25 10.6 42.3 5.25 24.1 8.83 0.219 35.6 25 68.1 0.069 0.234 0.00324 0.055 5 14.5 45.2 5.17 30.2 8.75 0.23 25.2 26 77.7 0.186 0.392 0.022 1.63 5.67 15.7 40.6 6.83 31.5 10.2 0.197 22.2 27 54.3 0.0621 0.0893 0.00997 0.755 5.5 13.8 44.8 6.67 32.3 8.83 0.181 50 28 71.8 0.039 0.0506 0.0186 0.863 5.58 15 45.1 6.25 29.9 7.33 0.213 27.5 29 81.6 0.0589 0.087 0.0293 1.45 6 17.5 40.6 6.25 33.2 8.58 51.1 30 57.6 0.0764 0.12 0.0105 1.06 6.17 19.4 45.4 6.25 34.6 6.42 36.8 31 61.5 0.0335 0.0372 0.0148 1.23 6.42 19.5 42.6 6.58 36.1 6.67 29.4 32 74.1 0.0422 0.0482 0.0129 1.13 5.92 18.9 44.2 7.08 32.8 8.25 26.7 33 60.7 0.0415 0.0442 0.0182 0.48 6.25 16.2 44.6 6.83 29.7 8.17 0.115 29.4 34 67.6 0.132 0.232 0.0116 0.653 5.42 14.2 42.4 6 27.2 10.9 0.224 51.1 35 59.3 0.0608 0.116 0.0186 0.95 5.83 14.3 43.2 5.83 29.8 8.42 0.168 37 36 61.6 0.0443 0.123 0.0164 0.736 6.25 15.8 40.3 6.92 34 8.42 39.9 37 69.3 0.185 0.343 5.83 5.25 40.8 5.58 31.8 9.67 41.8 Table 26: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under low nitrogen conditions. Growth conditions are specified in the experimental procedure section.

TABLE 27 Additional measured parameters in Sorghum accessions under low nitrogen growth conditions Seed Id 41 42 43 44 45 46 47 48 49 50 51 20 96.2 56.3 23.2 5.26 0.105 0.383 215 205 38.3 133 0.505 21 215 79.2 25.6 10.4 0.111 0.402 205 200 39 153 0.506 22 98.6 53.2 20.9 5.93 0.136 0.445 73.5 341 42.3 56.7 0.166 24 183 76.2 28.4 8.25 0.121 0.417 123 241 40.9 195 0.391 25 120 67.3 24.3 6.19 0.141 0.474 153 538 43.1 46.9 0.21 26 110 59.5 22.6 6.12 0.134 0.475 93.2 359 39.9 63.9 0.192 27 172 79.3 32.1 6.8 0.119 0.411 134 149 42.7 342 0.476 28 84.8 51.5 20.4 5.25 0.117 0.405 77.4 129 43.3 215 0.375 29 156 69.9 26.7 7.52 0.116 0.409 130 179 39 286 0.42 30 137 66.2 26.3 6.59 0.129 0.428 99.8 124 42.7 295 0.441 31 138 67.4 25.4 6.85 0.131 0.446 76.9 101 40.1 288 0.429 32 96.5 57.9 23.1 5.32 0.12 0.42 84.2 132 44 202 0.387 33 158 70.6 27.9 7.25 0.116 0.407 92.2 118 45.4 247 0.438 34 164 73.8 28.9 7.19 0.115 0.411 139 177 44.8 289 0.439 35 138 66.9 27.6 6.27 0.107 0.4 113 144 42.6 254 0.442 36 135 65.4 25.5 6.57 0.121 0.414 95.5 127 43.8 316 0.43 37 166 76 30.3 6.82 0.109 0.395 129 180 46.7 232 0.417 Table 27: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under low nitrogen conditions. Growth conditions are specified in the experimental procedure section.

TABLE 28 Measured parameters in Sorghum accessions under drought conditions Seed Id 52 53 54 55 56 57 58 59 60 61 62 63 20 0.215 0.205 0.0259 2.36 0.653 0.251 5.33 10.8 38.3 4.5 22.2 7.75 21 0.205 0.2 0.0306 2.44 0.823 0.255 5.5 8 39 5.75 18.5 7.92 22 0.0735 0.341 0.0194 3.67 1.58 0.181 5.83 16 42.3 5.75 30.3 8.67 24 0.123 0.241 0.0356 2.44 1.65 0.365 5.25 10.7 40.9 5.25 22.6 8.25 25 0.153 0.538 0.0252 2.7 0.959 0.189 5.25 13.8 43.1 5.5 27.9 8.17 26 0.0932 0.359 0.0222 3.03 1.32 0.182 6.25 16.3 39.9 6 32.7 9.38 27 0.134 0.149 0.05 2.42 3.47 0.358 6.5 15.2 42.7 6.17 32.2 9.12 28 0.0774 0.129 0.0275 2.19 2.76 0.175 5.75 13.5 43.3 5.83 28.9 8.58 29 0.13 0.179 0.0511 2.57 4.03 0.384 6.5 16.4 39 5.17 26.8 9.5 30 0.0998 0.124 0.0368 2.26 3.03 0.265 6.25 17.6 42.7 5.92 34.2 7.83 31 0.0769 0.101 0.0294 2.19 3.13 0.215 6.75 15.8 40.1 6.08 30.5 7.25 32 0.0842 0.132 0.0267 2.16 3.13 0.182 6.25 17 44 5.92 30.6 9 33 0.0922 0.118 0.0294 2.42 2.39 0.343 6.42 13.9 45.4 6.08 27.2 7.5 34 0.139 0.177 0.0511 2.71 3.34 0.479 6.33 14.8 44.8 6.08 27.6 10 35 0.113 0.144 0.037 2.29 2.7 0.246 5.5 12.5 42.6 5.42 28 8.38 36 0.0955 0.127 0.0399 2.08 4.19 0.219 6.33 17.6 43.8 5.33 29.3 8.67 37 0.129 0.18 0.0418 2.52 2.98 0.26 5.58 15.9 46.7 5.5 30.4 10 Table 28: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 29 Additional measured parameters in Sorghum accessions under drought growth conditions Seed Id 64 65 66 67 68 69 70 71 72 73 74 75 76 77 20 38 7.08 50.2 7.75 38 22.1 83.1 52.8 21.6 4.83 132 0.10 21 30.8 8.58 45.2 7.92 30.8 0.10 0.385 16.8 108 64.5 21.9 6.31 128 0.18 22 111 9.08 92.1 8.67 60.8 9.19 88.7 56.6 21.6 5.16 257 0.16 24 42.8 9 67.2 8.25 42.8 0.12 0.411 104 136 64.4 22 7.78 257 0.22 25 49.6 9.58 73.9 8.17 49.6 0.17 26 49.8 9.75 100 9.38 49.8 0.11 0.41 3.24 90.8 53.2 21 5.28 8.76 0.21 27 46.9 9.08 58.7 9.12 46.9 22 124 71.7 28.6 5.49 248 0.15 28 41.9 7.75 70.8 8.58 41.9 0.10 0.373 9.97 86.1 55.6 21.3 5.04 197 0.08 29 46.1 8.5 67.7 8.25 46.1 0.09 0.364 18.6 85.2 53 20.8 5.07 213 0.14 30 50.2 7.08 68.5 7.83 50.2 29.3 113 69.8 24.7 5.77 325 31 43.6 6.75 65.7 13.1 43.6 10.5 101 65.1 24.3 5.37 282 0.11 32 50.8 8.25 79.2 9 50.9 14.8 80.4 55.3 21.9 4.66 300 0.12 33 42.4 7.92 57.7 7.5 42.4 12.9 127 69.1 25 6.35 292 0.11 34 45.5 9.83 78.6 10 45.5 18.2 86.4 53.3 19.5 5.58 90.2 0.27 35 50.4 8.5 60.8 8.38 50.4 11.6 92.3 56.3 20.4 5.76 105 0.13 36 48.8 9.17 71.2 8.67 53.8 18.6 77.9 49.1 16.8 5.86 148 0.12 37 49.8 10.6 73.9 9.5 51.4 0.12 0.406 16.4 76.9 51.9 18.9 5.1 84.6 Table 29: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 30 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal or drought stress conditions across Sorghum accessions Gene Exp. Corr. Gene Exp. Corr. Name R P value Set ID set Name R P value Set ID set LNU280 0.75 1.91E−02 B 6 LNU278 0.75 1.19E−02 G 67 LNU85 0.71 3.17E−02 B 6 LNU202 0.73 2.45E−02 B 26 LNU279 0.70 3.53E−02 A 6 LNU202 0.71 3.09E−02 B 26 LNU32 0.85 3.53E−03 A 6 LNU84 0.79 6.65E−03 I 58 LNU280 0.70 3.52E−02 B 7 LNU84 0.76 1.11E−02 F 33 LNU279 0.76 1.73E−02 A 7 LNU87 0.71 2.11E−02 F 33 LNU32 0.86 2.96E−03 A 7 LNU25 0.74 1.38E−02 D 33 LNU278 0.73 1.63E−02 H 53 LNU87 0.72 1.97E−02 B 1 LNU87 0.71 2.11E−02 C 15 LNU87 0.71 2.17E−02 B 1 LNU280 0.89 1.22E−03 B 9 LNU202 0.71 3.11E−02 B 24 LNU279 0.76 1.74E−02 C 8 LNU202 0.71 3.11E−02 B 27 LNU280 0.73 1.59E−02 D 47 LNU84 0.89 3.10E−03 G 77 LNU87 0.83 2.92E−03 D 47 LNU84 0.80 1.82E−02 G 77 LNU84 0.70 2.31E−02 D 29 LNU280 0.87 4.92E−03 G 77 LNU279 0.74 1.53E−02 G 72 LNU279 0.82 4.60E−02 E 39 LNU84 0.80 5.67E−03 I 74 LNU84 0.72 1.82E−02 I 56 LNU279 0.73 1.73E−02 G 74 LNU202 0.71 2.07E−02 H 54 LNU279 0.70 2.29E−02 F 74 LNU278 0.95 7.45E−05 F 31 LNU84 0.72 1.86E−02 I 73 LNU280 0.76 1.86E−02 D 31 LNU84 0.70 2.36E−02 I 75 LNU279 0.71 2.23E−02 B 17 LNU280 0.77 9.16E−03 H 75 LNU280 0.77 9.13E−03 A 17 LNU278 0.78 8.14E−03 B 11 LNU87 0.72 1.97E−02 B 20 LNU278 0.76 1.04E−02 B 11 LNU25 0.75 1.26E−02 I 57 LNU84 0.95 2.28E−05 I 61 LNU279 0.75 1.94E−02 B 3 LNU278 0.71 2.26E−02 E 36 LNU202 0.76 1.82E−02 B 3 LNU280 0.71 2.11E−02 G 63 LNU280 0.88 1.84E−03 A 3 LNU202 0.73 2.45E−02 B 23 LNU279 0.86 1.29E−03 F 40 LNU280 0.76 1.15E−02 G 65 LNU84 0.75 1.27E−02 D 40 LNU202 0.87 1.02E−03 I 67 LNU280 0.76 1.78E−02 C 3 LNU278 0.89 5.06E−04 I 67 LNU202 0.76 1.14E−02 H 57 LNU280 0.78 8.43E−03 C 17 Table 30. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

TABLE 31 Correlation between the expression level of selected LNU homologous genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal or drought stress conditions across Sorghum accessions Gene Exp. Correl. Gene Exp. Correl. Name R P value Set Set ID Name R P value Set Set ID LNU267_H2 0.82 7.37E−03 C 6 LNU265_H0 0.81 4.77E−03 G 63 LNU267_H2 0.82 7.37E−03 C 6 LNU265_H0 0.72 1.84E−02 G 63 LNU74_H173 0.85 3.59E−03 C 6 LNU265_H0 0.81 4.77E−03 G 63 LNU74_H173 0.83 5.54E−03 C 6 LNU265_H0 0.72 1.84E−02 G 63 LNU74_H173 0.85 3.59E−03 C 6 LNU153_H6 0.80 5.43E−03 G 63 LNU74_H173 0.83 5.54E−03 C 6 LNU153_H6 0.80 5.43E−03 G 63 LNU46_H58 0.86 2.71E−03 C 6 LNU271_H4 0.90 8.49E−04 C 23 LNU46_H58 0.73 2.66E−02 C 6 LNU271_H4 0.90 9.96E−04 C 23 LNU46_H58 0.72 2.74E−02 C 6 LNU271_H4 0.90 8.49E−04 C 23 LNU46_H58 0.86 2.71E−03 C 6 LNU271_H4 0.90 9.96E−04 C 23 LNU46_H58 0.73 2.66E−02 C 6 LNU45_H259 0.71 3.28E−02 C 23 LNU46_H58 0.72 2.74E−02 C 6 LNU71_H3 0.81 4.39E−03 I 65 LNU2_H4 0.77 1.61E−02 B 6 LNU71_H3 0.81 4.39E−03 I 65 LNU2_H??? 0.77 1.61E−02 B 6 LNU28_H4 0.77 9.28E−03 H 65 LNU2_H4 0.77 1.61E−02 B 6 LNU28_H4 0.76 1.12E−02 H 65 LNU73_H2 0.78 1.37E−02 B 6 LNU28_H4 0.77 9.28E−03 H 65 LNU73_H2 0.74 2.30E−02 B 6 LNU28_H4 0.76 1.12E−02 H 65 LNU73_H2 0.78 1.37E−02 B 6 LNU71_H3 0.72 1.99E−02 G 65 LNU73_H2 0.74 2.30E−02 B 6 LNU71_H3 0.72 1.99E−02 G 65 LNU76_H55 0.90 8.36E−04 B 6 LNU192_H3 0.75 1.16E−02 G 65 LNU76_H55 0.79 1.10E−02 B 6 LNU192_H3 0.75 1.16E−02 G 65 LNU76_H55 0.90 8.36E−04 B 6 LNU153_H6 0.73 1.59E−02 G 65 LNU76_H55 0.79 1.10E−02 B 6 LNU153_H6 0.73 1.59E−02 G 65 LNU35_H4 0.72 2.88E−02 B 6 LNU109_H2 0.82 3.46E−03 F 38 LNU35_H4 0.72 2.88E−02 B 6 LNU109_H2 0.73 1.67E−02 F 38 LNU223_H6 0.74 2.25E−02 B 6 LNU109_H2 0.82 3.46E−03 F 38 LNU223_H6 0.74 2.25E−02 B 6 LNU109_H2 0.73 1.67E−02 F 38 LNU267_H2 0.75 2.05E−02 A 6 LNU153_H6 0.73 1.75E−02 F 38 LNU267_H2 0.72 3.00E−02 A 6 LNU153_H6 0.73 1.75E−02 F 38 LNU267_H2 0.75 2.05E−02 A 6 LNU28_H4 0.90 4.11E−04 E 38 LNU267_H2 0.72 3.00E−02 A 6 LNU28_H4 0.89 5.37E−04 E 38 LNU263_H4 0.75 2.03E−02 A 6 LNU28_H4 0.90 4.11E−04 E 38 LNU263_H4 0.75 2.07E−02 A 6 LNU28_H4 0.89 5.37E−04 E 38 LNU263_H5 0.75 1.93E−02 A 6 LNU153_H5 0.79 6.64E−03 B 25 LNU263_H5 0.74 2.14E−02 A 6 LNU153_H5 0.79 6.64E−03 B 25 LNU263_H4 0.75 2.03E−02 A 6 LNU45_H258 0.77 9.31E−03 A 25 LNU263_H4 0.75 2.07E−02 A 6 LNU45_H258 0.77 9.31E−03 A 25 LNU263_H5 0.75 1.93E−02 A 6 LNU263_H4 0.73 1.64E−02 I 67 LNU263_H5 0.74 2.14E−02 A 6 LNU263_H4 0.71 2.20E−02 I 67 LNU32_H2 0.76 1.78E−02 A 6 LNU263_H4 0.73 1.64E−02 I 67 LNU32_H2 0.76 1.78E−02 A 6 LNU263_H4 0.71 2.20E−02 I 67 LNU109_H2 0.88 1.67E−03 A 6 LNU19_H1 0.75 1.26E−02 H 67 LNU109_H2 0.88 1.78E−03 A 6 LNU263_H5 0.71 2.22E−02 H 67 LNU109_H2 0.88 1.67E−03 A 6 LNU263_H5 0.71 2.22E−02 H 67 LNU109_H2 0.88 1.78E−03 A 6 LNU271_H4 0.83 2.65E−03 H 67 LNU45_H259 0.75 1.93E−02 A 6 LNU271_H4 0.72 1.82E−02 H 67 LNU73_H2 0.74 1.46E−02 F 45 LNU271_H4 0.83 2.65E−03 H 67 LNU73_H2 0.74 1.46E−02 F 45 LNU271_H4 0.72 1.82E−02 H 67 LNU267_H2 0.87 2.55E−03 C 7 LNU223_H6 0.78 7.24E−03 H 67 LNU267_H2 0.71 3.24E−02 C 7 LNU223_H6 0.78 7.24E−03 H 67 LNU267_H2 0.87 2.55E−03 C 7 LNU271_H4 0.90 8.49E−04 C 26 LNU267_H2 0.71 3.24E−02 C 7 LNU271_H4 0.90 9.96E−04 C 26 LNU74_H173 0.81 8.49E−03 C 7 LNU271_H4 0.90 8.49E−04 C 26 LNU74_H173 0.77 1.44E−02 C 7 LNU271_H4 0.90 9.96E−04 C 26 LNU74_H173 0.81 8.49E−03 C 7 LNU45_H259 0.71 3.28E−02 C 26 LNU74_H173 0.77 1.44E−02 C 7 LNU266_H0 0.91 2.13E−04 I 58 LNU46_H58 0.85 3.94E−03 C 7 LNU266_H0 0.87 1.17E−03 I 58 LNU46_H58 0.85 3.94E−03 C 7 LNU266_H0 0.91 2.13E−04 I 58 LNU19_H1 0.74 2.38E−02 B 7 LNU266_H0 0.87 1.17E−03 I 58 LNU73_H2 0.74 2.27E−02 B 7 LNU271_H4 0.86 1.38E−03 I 58 LNU73_H2 0.74 2.27E−02 B 7 LNU271_H4 0.76 1.14E−02 I 58 LNU76_H55 0.90 8.98E−04 B 7 LNU271_H4 0.86 1.38E−03 I 58 LNU76_H55 0.76 1.78E−02 B 7 LNU271_H4 0.76 1.14E−02 I 58 LNU76_H55 0.90 8.98E−04 B 7 LNU266_H0 0.81 4.11E−03 H 58 LNU76_H55 0.76 1.78E−02 B 7 LNU266_H0 0.75 1.16E−02 H 58 LNU223_H6 0.76 1.80E−02 B 7 LNU266_H0 0.81 4.11E−03 H 58 LNU223_H6 0.76 1.80E−02 B 7 LNU266_H0 0.75 1.16E−02 H 58 LNU267_H2 0.81 7.62E−03 A 7 LNU268_H2 0.81 4.08E−03 H 58 LNU267_H2 0.79 1.15E−02 A 7 LNU268_H2 0.80 4.97E−03 H 58 LNU267_H2 0.81 7.62E−03 A 7 LNU268_H2 0.81 4.08E−03 H 58 LNU267_H2 0.79 1.15E−02 A 7 LNU268_H2 0.80 4.97E−03 H 58 LNU263_H4 0.76 1.81E−02 A 7 LNU121_H1 0.74 1.37E−02 E 33 LNU263_H4 0.75 1.98E−02 A 7 LNU121_H1 0.71 2.17E−02 E 33 LNU263_H4 0.76 1.81E−02 A 7 LNU268_H2 0.92 1.97E−04 E 33 LNU263_H4 0.75 1.98E−02 A 7 LNU268_H2 0.90 3.81E−04 E 33 LNU32_H2 0.73 2.63E−02 A 7 LNU268_H2 0.92 1.97E−04 E 33 LNU32_H2 0.73 2.63E−02 A 7 LNU268_H2 0.90 3.81E−04 E 33 LNU109_H2 0.88 1.95E−03 A 7 LNU48_H1 0.85 1.63E−03 E 33 LNU109_H2 0.86 2.61E−03 A 7 LNU48_H1 0.85 1.63E−03 E 33 LNU109_H2 0.88 1.95E−03 A 7 LNU34_H1 0.78 8.40E−03 E 33 LNU109_H2 0.86 2.61E−03 A 7 LNU34_H1 0.78 8.40E−03 E 33 LNU45_H259 0.75 2.09E−02 A 7 LNU28_H4 0.71 2.27E−02 D 33 LNU45_H259 0.78 8.02E−03 I 53 LNU28_H4 0.71 2.27E−02 D 33 LNU45_H259 0.78 8.02E−03 I 53 LNU45_H259 0.86 1.53E−03 D 33 LNU69_H4 0.70 2.34E−02 H 53 LNU45_H259 0.85 1.76E−03 D 33 LNU69_H4 0.72 1.97E−02 G 53 LNU267_H2 0.73 1.73E−02 A 18 LNU2_H4 0.71 2.09E−02 B 15 LNU267_H2 0.71 2.20E−02 A 18 LNU2_H??? 0.71 2.09E−02 B 15 LNU267_H2 0.73 1.73E−02 A 18 LNU2_H4 0.71 2.09E−02 B 15 LNU267_H2 0.71 2.20E−02 A 18 LNU267_H2 0.77 9.13E−03 B 15 LNU73_H2 0.73 1.55E−02 A 18 LNU267_H2 0.77 9.13E−03 B 15 LNU73_H2 0.71 2.03E−02 A 18 LNU153_H5 0.83 3.20E−03 B 15 LNU73_H2 0.73 1.55E−02 A 18 LNU153_H5 0.83 3.20E−03 B 15 LNU73_H2 0.71 2.03E−02 A 18 LNU45_H259 0.75 1.20E−02 I 53 LNU76_H55 0.76 1.06E−02 A 18 LNU45_H259 0.75 1.20E−02 I 53 LNU76_H55 0.75 1.17E−02 A 18 LNU28_H4 0.76 1.02E−02 G 53 LNU76_H55 0.76 1.06E−02 A 18 LNU28_H4 0.76 1.02E−02 G 53 LNU76_H55 0.75 1.17E−02 A 18 LNU153_H5 0.78 7.18E−03 G 53 LNU52_H6 0.84 2.20E−03 B 1 LNU153_H5 0.78 7.18E−03 G 53 LNU52_H6 0.74 1.36E−02 B 1 LNU239_H10 0.72 1.81E−02 E 30 LNU52_H6 0.84 2.20E−03 B 1 LNU239_H10 0.72 1.81E−02 E 30 LNU52_H6 0.74 1.36E−02 B 1 LNU121_H1 0.73 1.72E−02 D 30 LNU46_H60 0.72 1.85E−02 B 1 LNU121_H1 0.71 2.19E−02 D 30 LNU46_H60 0.72 1.85E−02 B 1 LNU45_H259 0.77 9.46E−03 C 15 LNU35_H4 0.80 5.52E−03 H 59 LNU45_H259 0.74 1.43E−02 C 15 LNU35_H4 0.77 8.61E−03 H 59 LNU76_H55 0.80 5.70E−03 H 30 LNU35_H4 0.80 5.52E−03 H 59 LNU76_H55 0.80 5.70E−03 H 30 LNU35_H4 0.77 8.61E−03 H 59 LNU28_H4 0.80 4.98E−03 G 30 LNU73_H2 0.78 8.29E−03 F 34 LNU28_H4 0.72 1.96E−02 G 30 LNU73_H2 0.78 8.29E−03 F 34 LNU28_H4 0.80 4.98E−03 G 30 LNU73_H2 0.76 1.00E−02 A 19 LNU28_H4 0.72 1.96E−02 G 30 LNU73_H2 0.72 1.95E−02 I 62 LNU153_H5 0.76 1.15E−02 G 30 LNU271_H4 0.73 1.58E−02 I 62 LNU153_H5 0.76 1.15E−02 G 30 LNU271_H4 0.73 1.58E−02 I 62 LNU52_H6 0.71 2.05E−02 F 30 LNU35_H4 0.75 1.25E−02 H 62 LNU52_H6 0.71 2.27E−02 F 30 LNU35_H4 0.74 1.39E−02 H 62 LNU52_H6 0.71 2.05E−02 F 30 LNU35_H4 0.75 1.25E−02 H 62 LNU52_H6 0.71 2.27E−02 F 30 LNU35_H4 0.74 1.39E−02 H 62 LNU7_H125 0.71 2.09E−02 F 30 LNU153_H5 0.77 9.81E−03 H 62 LNU7_H125 0.71 2.09E−02 F 30 LNU153_H5 0.77 9.81E−03 H 62 LNU7_H124 0.71 2.09E−02 F 30 LNU239_H10 0.75 1.29E−02 A 22 LNU7_H125 0.71 2.09E−02 F 30 LNU239_H10 0.75 1.29E−02 A 22 LNU7_H124 0.71 2.09E−02 F 30 LNU76_H55 0.76 1.10E−02 H 64 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LNU74_H172 0.82 4.02E−03 B 12 LNU153_H6 0.84 2.34E−03 B 17 LNU74_H172 0.82 4.02E−03 B 12 LNU128_H12 0.72 2.00E−02 A 17 LNU45_H259 0.80 5.93E−03 B 12 LNU128_H12 0.72 2.00E−02 A 17 LNU45_H259 0.80 5.93E−03 B 12 LNU13_H1 0.80 4.97E−03 A 17 LNU153_H6 0.72 1.99E−02 B 12 LNU13_H1 0.78 7.23E−03 A 17 LNU153_H6 0.72 1.99E−02 B 12 LNU13_H1 0.80 4.97E−03 A 17 LNU128_H12 0.76 1.11E−02 A 12 LNU13_H1 0.78 7.23E−03 A 17 LNU128_H12 0.76 1.11E−02 A 12 LNU268_H2 0.87 1.22E−03 A 17 LNU51_H2 0.71 2.07E−02 A 12 LNU268_H2 0.82 3.58E−03 A 17 LNU51_H2 0.71 2.07E−02 A 12 LNU268_H2 0.87 1.22E−03 A 17 LNU67_H4 0.80 5.06E−03 A 12 LNU268_H2 0.82 3.58E−03 A 17 LNU265_H0 0.81 4.14E−03 A 12 LNU52_H6 0.72 1.91E−02 A 17 LNU265_H0 0.81 4.14E−03 A 12 LNU52_H6 0.72 1.91E−02 A 17 LNU121_H1 0.87 1.04E−03 H 72 LNU153_H6 0.89 5.61E−04 A 17 LNU121_H1 0.77 9.39E−03 H 72 LNU153_H6 0.89 5.61E−04 A 17 LNU121_H1 0.87 1.04E−03 H 72 LNU13_H1 0.79 6.40E−03 I 60 LNU121_H1 0.77 9.39E−03 H 72 LNU13_H1 0.79 6.40E−03 I 60 LNU2_H4 0.78 8.24E−03 H 72 LNU71_H3 0.84 2.54E−03 I 60 LNU2_H??? 0.78 8.24E−03 H 72 LNU71_H3 0.83 2.96E−03 I 60 LNU2_H4 0.78 8.24E−03 H 72 LNU71_H3 0.84 2.54E−03 I 60 LNU51_H2 0.85 1.96E−03 H 72 LNU71_H3 0.83 2.96E−03 I 60 LNU51_H2 0.85 1.96E−03 H 72 LNU74_H172 0.74 1.44E−02 I 60 LNU32_H2 0.89 5.20E−04 H 72 LNU74_H172 0.74 1.44E−02 I 60 LNU32_H2 0.89 5.20E−04 H 72 LNU192_H3 0.87 1.08E−03 I 60 LNU266_H0 0.73 2.68E−02 A 4 LNU192_H3 0.72 1.77E−02 I 60 LNU266_H0 0.73 2.68E−02 A 4 LNU192_H3 0.87 1.08E−03 I 60 LNU268_H2 0.75 1.98E−02 A 4 LNU192_H3 0.72 1.77E−02 I 60 LNU268_H2 0.72 2.84E−02 A 4 LNU46_H60 0.73 1.71E−02 I 60 LNU268_H2 0.75 1.98E−02 A 4 LNU46_H60 0.73 1.71E−02 I 60 LNU268_H2 0.72 2.84E−02 A 4 LNU73_H2 0.77 8.83E−03 E 35 LNU153_H6 0.77 1.48E−02 A 4 LNU35_H4 0.76 1.00E−02 E 35 LNU153_H6 0.77 1.48E−02 A 4 LNU35_H4 0.76 1.00E−02 E 35 LNU46_H58 0.72 1.93E−02 D 41 LNU52_H6 0.84 2.20E−03 B 20 LNU46_H58 0.72 1.93E−02 D 41 LNU52_H6 0.74 1.36E−02 B 20 LNU268_H2 0.71 2.18E−02 I 74 LNU52_H6 0.84 2.20E−03 B 20 LNU268_H2 0.71 2.18E−02 I 74 LNU52_H6 0.74 1.36E−02 B 20 LNU121_H1 0.83 2.88E−03 H 74 LNU46_H60 0.72 1.85E−02 B 20 LNU121_H1 0.78 8.38E−03 H 74 LNU46_H60 0.72 1.85E−02 B 20 LNU121_H1 0.83 2.88E−03 H 74 LNU109_H2 0.74 1.51E−02 I 71 LNU121_H1 0.78 8.38E−03 H 74 LNU109_H2 0.74 1.51E−02 I 71 LNU51_H2 0.77 9.69E−03 H 74 LNU216_H4 0.74 1.53E−02 G 71 LNU51_H2 0.77 9.69E−03 H 74 LNU216_H3 0.75 1.27E−02 G 71 LNU192_H3 0.77 8.74E−03 H 74 LNU216_H3 0.74 1.41E−02 G 71 LNU192_H3 0.70 2.33E−02 H 74 LNU216_H4 0.74 1.53E−02 G 71 LNU192_H3 0.77 8.74E−03 H 74 LNU216_H3 0.75 1.27E−02 G 71 LNU192_H3 0.70 2.33E−02 H 74 LNU216_H3 0.74 1.41E−02 G 71 LNU32_H2 0.76 1.06E−02 H 74 LNU45_H259 0.75 2.10E−02 C 3 LNU32_H2 0.76 1.06E−02 H 74 LNU153_H6 0.72 2.81E−02 C 3 LNU89_H5 0.71 2.03E−02 H 74 LNU153_H6 0.72 2.81E−02 C 3 LNU89_H5 0.71 2.03E−02 H 74 LNU28_H4 0.77 1.62E−02 B 3 LNU86_H0 0.72 2.01E−02 H 74 LNU28_H4 0.76 1.80E−02 B 3 LNU86_H0 0.72 2.01E−02 H 74 LNU28_H4 0.77 1.62E−02 B 3 LNU46_H58 0.75 1.23E−02 G 74 LNU28_H4 0.76 1.80E−02 B 3 LNU46_H58 0.75 1.23E−02 G 74 LNU153_H6 0.83 5.32E−03 B 3 LNU153_H5 0.71 3.05E−02 B 5 LNU153_H6 0.83 5.32E−03 B 3 LNU153_H5 0.71 3.05E−02 B 5 LNU128_H12 0.72 2.75E−02 A 3 LNU268_H2 0.71 3.17E−02 A 5 LNU128_H12 0.72 2.75E−02 A 3 LNU268_H2 0.71 3.29E−02 A 5 LNU13_H1 0.80 9.65E−03 A 3 LNU268_H2 0.71 3.17E−02 A 5 LNU13_H1 0.78 1.27E−02 A 3 LNU268_H2 0.71 3.29E−02 A 5 LNU13_H1 0.80 9.65E−03 A 3 LNU153_H6 0.80 1.01E−02 A 5 LNU13_H1 0.78 1.27E−02 A 3 LNU153_H6 0.80 1.01E−02 A 5 LNU266_H0 0.76 1.85E−02 A 3 LNU263_H4 0.75 1.20E−02 F 43 LNU266_H0 0.71 3.35E−02 A 3 LNU263_H4 0.75 1.32E−02 F 43 LNU266_H0 0.76 1.85E−02 A 3 LNU263_H4 0.75 1.20E−02 F 43 LNU266_H0 0.71 3.35E−02 A 3 LNU263_H4 0.75 1.32E−02 F 43 LNU268_H2 0.85 3.93E−03 A 3 LNU46_H58 0.72 1.86E−02 D 43 LNU268_H2 0.79 1.06E−02 A 3 LNU46_H58 0.72 1.86E−02 D 43 LNU268_H2 0.85 3.93E−03 A 3 LNU121_H1 0.88 8.89E−04 H 73 LNU268_H2 0.79 1.06E−02 A 3 LNU121_H1 0.78 8.16E−03 H 73 LNU52_H6 0.75 1.94E−02 A 3 LNU121_H1 0.88 8.89E−04 H 73 LNU52_H6 0.75 1.94E−02 A 3 LNU121_H1 0.78 8.16E−03 H 73 LNU67_H4 0.76 1.73E−02 A 3 LNU2_H4 0.72 1.80E−02 H 73 LNU192_H3 0.73 2.47E−02 A 3 LNU2_H??? 0.72 1.80E−02 H 73 LNU192_H3 0.73 2.47E−02 A 3 LNU2_H4 0.72 1.80E−02 H 73 LNU265_H0 0.70 3.43E−02 A 3 LNU51_H2 0.84 2.50E−03 H 73 LNU265_H0 0.70 3.43E−02 A 3 LNU51_H2 0.84 2.50E−03 H 73 LNU46_H60 0.73 2.57E−02 A 3 LNU32_H2 0.85 1.87E−03 H 73 LNU46_H60 0.73 2.57E−02 A 3 LNU32_H2 0.85 1.87E−03 H 73 LNU153_H6 0.96 5.15E−05 A 3 LNU265_H0 0.70 2.29E−02 H 73 LNU153_H6 0.96 5.15E−05 A 3 LNU265_H0 0.70 2.41E−02 H 73 LNU216_H4 0.82 3.31E−03 F 40 LNU265_H0 0.70 2.29E−02 H 73 LNU216_H3 0.86 1.42E−03 F 40 LNU265_H0 0.70 2.41E−02 H 73 LNU216_H3 0.86 1.43E−03 F 40 LNU263_H4 0.72 1.77E−02 F 42 LNU216_H4 0.82 3.31E−03 F 40 LNU263_H4 0.71 2.06E−02 F 42 LNU216_H3 0.86 1.42E−03 F 40 LNU263_H4 0.72 1.77E−02 F 42 LNU216_H3 0.86 1.43E−03 F 40 LNU263_H4 0.71 2.06E−02 F 42 LNU263_H4 0.80 5.34E−03 F 40 LNU46_H58 0.75 1.27E−02 D 42 LNU263_H4 0.80 5.88E−03 F 40 LNU46_H58 0.75 1.27E−02 D 42 LNU263_H5 0.71 2.04E−02 F 40 LNU216_H4 0.77 9.16E−03 I 75 LNU263_H4 0.80 5.34E−03 F 40 LNU216_H4 0.77 9.16E−03 I 75 LNU263_H4 0.80 5.88E−03 F 40 LNU46_H60 0.70 2.29E−02 I 75 LNU263_H5 0.71 2.04E−02 F 40 LNU46_H60 0.70 2.29E−02 I 75 LNU271_H4 0.73 1.71E−02 F 40 LNU2_H4 0.75 1.24E−02 H 75 LNU271_H4 0.73 1.71E−02 F 40 LNU2_H??? 0.75 1.24E−02 H 75 LNU266_H0 0.70 2.34E−02 E 40 LNU2_H4 0.75 1.24E−02 H 75 LNU266_H0 0.70 2.34E−02 E 40 LNU32_H2 0.73 1.67E−02 H 75 LNU74_H173 0.73 1.63E−02 D 40 LNU32_H2 0.73 1.67E−02 H 75 LNU74_H173 0.73 1.63E−02 D 40 LNU73_H2 0.73 1.56E−02 G 75 LNU45_H258 0.79 6.14E−03 D 40 LNU32_H2 0.75 1.25E−02 G 75 LNU45_H258 0.79 6.14E−03 D 40 LNU32_H2 0.75 1.25E−02 G 75 LNU46_H58 0.80 5.34E−03 D 40 LNU45_H259 0.83 2.77E−03 G 75 LNU46_H58 0.80 5.34E−03 D 40 LNU45_H259 0.78 8.22E−03 G 75 LNU266_H0 0.79 1.14E−02 C 3 LNU266_H0 0.74 1.45E−02 F 44 LNU266_H0 0.77 1.42E−02 C 3 LNU266_H0 0.74 1.45E−02 F 44 LNU266_H0 0.79 1.14E−02 C 3 LNU73_H2 0.70 2.37E−02 G 76 LNU266_H0 0.77 1.42E−02 C 3 LNU74_H173 0.80 5.37E−03 B 11 LNU74_H173 0.79 1.16E−02 B 3 LNU74_H173 0.80 5.37E−03 B 11 LNU74_H173 0.79 1.16E−02 B 3 LNU266_H0 0.72 1.93E−02 A 11 LNU192_H3 0.76 1.74E−02 B 3 LNU266_H0 0.72 1.93E−02 A 11 LNU192_H3 0.76 1.74E−02 B 3 LNU153_H6 0.71 2.21E−02 A 11 LNU266_H0 0.74 2.24E−02 A 3 LNU153_H6 0.71 2.21E−02 A 11 LNU266_H0 0.74 2.24E−02 A 3 LNU266_H0 0.81 4.88E−03 F 50 LNU268_H2 0.77 1.61E−02 A 3 LNU266_H0 0.77 9.63E−03 F 50 LNU268_H2 0.76 1.65E−02 A 3 LNU266_H0 0.81 4.88E−03 F 50 LNU268_H2 0.77 1.61E−02 A 3 LNU266_H0 0.77 9.63E−03 F 50 LNU268_H2 0.76 1.65E−02 A 3 LNU266_H0 0.72 2.00E−02 E 50 LNU153_H6 0.90 9.44E−04 A 3 LNU266_H0 0.72 2.00E−02 E 50 LNU153_H6 0.90 9.44E−04 A 3 LNU266_H0 0.80 5.96E−03 D 50 LNU216_H3 0.70 2.30E−02 F 32 LNU266_H0 0.79 7.09E−03 D 50 LNU216_H3 0.70 2.34E−02 F 32 LNU266_H0 0.80 5.96E−03 D 50 LNU216_H3 0.70 2.30E−02 F 32 LNU266_H0 0.79 7.09E−03 D 50 LNU216_H3 0.70 2.34E−02 F 32 LNU46_H58 0.81 4.21E−03 D 50 LNU266_H0 0.72 1.83E−02 F 32 LNU46_H58 0.81 4.21E−03 D 50 LNU266_H0 0.72 1.83E−02 F 32 LNU266_H0 0.72 1.96E−02 I 61 LNU51_H2 0.74 1.40E−02 I 57 LNU266_H0 0.72 1.96E−02 I 61 LNU51_H2 0.74 1.40E−02 I 57 LNU271_H4 0.87 9.39E−04 I 61 LNU74_H172 0.74 1.54E−02 G 57 LNU271_H4 0.85 1.86E−03 I 61 LNU74_H172 0.70 2.39E−02 G 57 LNU271_H4 0.87 9.39E−04 I 61 LNU74_H172 0.74 1.54E−02 G 57 LNU271_H4 0.85 1.86E−03 I 61 LNU74_H172 0.70 2.39E−02 G 57 LNU45_H259 0.80 4.99E−03 F 36 LNU45_H259 0.76 1.14E−02 G 57 LNU45_H259 0.80 4.99E−03 F 36 LNU45_H259 0.74 1.46E−02 G 57 LNU121_H1 0.77 9.58E−03 E 36 LNU45_H258 0.72 1.97E−02 G 57 LNU121_H1 0.77 9.26E−03 E 36 LNU45_H258 0.71 2.04E−02 G 57 LNU121_H1 0.77 9.58E−03 E 36 LNU45_H259 0.76 1.14E−02 G 57 LNU67_H4 0.73 1.57E−02 E 36 LNU45_H259 0.74 1.46E−02 G 57 LNU86_H0 0.74 1.37E−02 E 36 LNU45_H258 0.72 1.97E−02 G 57 LNU86_H0 0.74 1.37E−02 E 36 LNU45_H258 0.71 2.04E−02 G 57 LNU71_H3 0.71 2.15E−02 I 63 LNU266_H0 0.81 4.59E−03 C 3 LNU71_H3 0.71 2.15E−02 I 63 LNU266_H0 0.79 6.43E−03 C 3 LNU28_H4 0.81 4.19E−03 H 63 LNU266_H0 0.81 4.59E−03 C 3 LNU28_H4 0.81 4.23E−03 H 63 LNU266_H0 0.79 6.43E−03 C 3 LNU28_H4 0.81 4.19E−03 H 63 LNU74_H173 0.70 2.36E−02 B 3 LNU28_H4 0.81 4.23E−03 H 63 LNU74_H173 0.70 2.36E−02 B 3 LNU71_H3 0.81 4.65E−03 G 63 LNU192_H3 0.72 1.98E−02 B 3 LNU71_H3 0.77 9.48E−03 G 63 LNU192_H3 0.72 1.98E−02 B 3 LNU71_H3 0.81 4.65E−03 G 63 LNU268_H2 0.79 6.71E−03 A 3 LNU71_H3 0.77 9.48E−03 G 63 LNU268_H2 0.79 6.95E−03 A 3 LNU192_H3 0.77 9.48E−03 G 63 LNU268_H2 0.79 6.71E−03 A 3 LNU192_H3 0.72 1.81E−02 G 63 LNU268_H2 0.79 6.95E−03 A 3 LNU192_H3 0.77 9.48E−03 G 63 LNU153_H6 0.85 1.63E−03 A 3 LNU192_H3 0.72 1.81E−02 G 63 LNU153_H6 0.85 1.63E−03 A 3 Table 31. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

Example 8 Production of Sorghum Transcriptom and High Throughput Correlation Analysis with Yield, Nue, and Abst Related Parameters Measured in Semi-Hydroponics Conditions Using 44K Sorguhm Oligonucleotide Micro-Arrays

Sorghum vigor related parameters under low nitrogen, 100 mM NaCl, low temperature (10±2° C.) and normal growth conditions—Ten Sorghum hybrids were grown in 3 repetitive plots, each containing 17 plants, at a net house under semi-hydroponics conditions. Briefly, the growing protocol was as follows: Sorghum seeds were sown in trays filled with a mix of vermiculite and peat in a 1:1 ratio. Following germination, the trays were transferred to the high salinity solution (100 mM NaCl in addition to the Full Hoagland solution), low temperature (10±2° C. in the presence of Full Hoagland solution), low nitrogen solution (the amount of total nitrogen was reduced in 90% from the full Hoagland solution (i.e., to a final concentration of 10% from full Hoagland solution, final amount of 1.2 mM N) or at Normal growth solution (Full Hoagland containing 16 mM N solution, at 28±2° C.). Plants were grown at 28±2° C.

Full Hoagland solution consists of: KNO₃—0.808 grams/liter, MgSO₄—0.12 grams/liter, KH₂PO₄—0.172 grams/liter and 0.01% (volume/volume) of ‘Super coratin’ micro elements (Iron-EDDHA [ethylenediamine-N,N′-bis(2-hydroxyphenylacetic acid)]—40.5 grams/liter; Mn—20.2 grams/liter; Zn 10.1 grams/liter; Co 1.5 grams/liter; and Mo 1.1 grams/liter), solution's pH should be 6.5-6.8].

Analyzed Sorghum tissues—All 10 selected Sorghum hybrids were sampled per each treatment. Three tissues [leaves, meristems and roots] growing at 100 mM NaCl, low temperature (10±2° C.), low Nitrogen (1.2 mM N) or under Normal conditions were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 32 below.

TABLE 32 Sorghum transcriptom expression sets under semi hydroponics conditions Expression set Set Id Sorghum roots under Low Nitrogen A Sorghum leaves under Low Nitrogen B Sorghum meristems under Low Nitrogen C Sorghum roots under Normal Growth D Sorghum leaves under Normal Growth E Sorghum meristems under Normal Growth F Sorghum roots under 100 mM NaCl G Sorghum leaves under 100 mM NaCl H Sorghum meristems under 100 mM NaCl I Sorghum roots under cold J Sorghum leaves under cold K Sorghum meristems under cold L Table 32: Provided are the Sorghum transcriptom expression sets. Cold conditions = 10 ± 2° C.; NaCl = 100 mM NaCl; low nitrogen = 1.2 mM Nitrogen; Normal conditions = 16 mM Nitrogen.

Experimental Results

10 different Sorghum hybrids were grown and characterized for the following parameters: “Leaf number Normal”=leaf number per plant under normal conditions (average of five plants); “Plant Height Normal”=plant height under normal conditions (average of five plants); “Root DW”—root dry weight per plant (average of five plants); The average for each of the measured parameter was calculated using the JMP software and values are summarized in Table 34, 35, 36 and 37 below. Subsequent correlation analysis was performed (Tables 38 and 39). Results were then integrated to the database.

TABLE 33 Sorghum correlated parameters (vectors) Correlation Set Correlation ID Plant Height TP 1 - Low Nitrogen 1 Plant Height TP2- Low Nitrogen 2 Plant Height TP3 - Low Nitrogen 3 Leaf TP1 - Low Nitrogen 4 Leaf TP2 - Low Nitrogen 5 Leaf TP3 - Low Nitrogen 6 DW Shoot/Plant - Low Nitrogen 7 DW Root/Plant - Low Nitrogen 8 SPAD - Low Nitrogen 9 Plant Height TP1 - 100 mM NaCl 10 Plant Height TP2- 100 mM NaCl 11 Plant Height TP3 - 100 mM NaCl 12 Leaf TP1 - 100 mM NaCl 13 Leaf TP2 -100 mM NaCl 14 Leaf TP3 - 100 mM NaCl 15 DW Shoot/Plant - 100 mM NaCl 16 DW Root/Plant - 100 mM NaCl 17 SPAD - 100 mM NaCl 18 Plant Height TP1-Cold 19 Plant Height TP2- Cold 20 Leaf TP1 - Cold 21 Leaf TP2 - Cold 22 Leaf TP3 - Cold 23 DW Shoot/Plant - Cold 24 DW Root/Plant - Cold 25 SPAD - Cold 26 Plant Height TP1-Normal 27 Plant Height TP2- Normal 28 Leaf TP1 -Normal 29 Leaf TP2 -Normal 30 Leaf TP3 -Normal 31 DW Shoot/Plant - Normal 32 DW Root/Plant - Normal 33 SPAD - Normal 34 Table 33: Provided are the Sorghum correlated parameters. Cold conditions = 10 ± 2° C.; NaCl = 100 mM NaCl; low nitrogen = 1.2 mM Nitrogen; Normal conditions = 16 mM Nitrogen * TP-1-2-3 refers to time points 1, 2 and 3.

TABLE 34 Sorghum accessions, measured parameters under low nitrogen growth conditions Seed ID 1 2 3 4 5 6 7 8 9 20 6.73 13.3 22.2 3 4 3.9 0.0823 0.0444 26.9 22 9.77 20.6 31.1 3.13 4.58 4.27 0.187 0.108 28 26 12.7 23.7 34.7 3.87 4.97 4.7 0.328 0.202 29.6 27 8.67 18 30 3.53 4.73 4.23 0.163 0.104 31.5 28 9.77 19.3 30.8 3.2 4.6 4.3 0.163 0.0777 29.6 29 9.23 19.2 29.9 3.13 4.7 4.57 0.156 0.0858 26.8 30 10.3 21.9 30.9 3.13 4.97 4.63 0.259 0.13 28.5 31 10.1 22.1 32.4 3.3 4.87 4.67 0.199 0.0944 28.2 34 7.93 18.2 29.4 3.07 4.67 3.97 0.13 0.0863 30.5 37 8.23 21 30.7 3.07 4.57 4.1 0.184 0.0924 27.6 Table 34: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under low nitrogen conditions. Growth conditions are specified in the experimental procedure section.

TABLE 35 Sorghum accessions, measured parameters under 100 mM NaCl growth conditions Seed ID 10 11 12 13 14 15 16 17 18 20 7.9 14.2 21.8 3 4 4 0.0943 0.05 32.7 22 9.5 16.3 23.2 3.13 4.37 4.13 0.186 0.104 35.1 26 10.9 20.4 30.4 3.4 4.87 4.57 0.202 0.124 28 27 7.93 13.3 22.8 3.07 4.6 4.43 0.137 0.0688 30.9 28 9.7 15.9 23.7 3.33 4.5 4.07 0.13 0.0757 34.5 29 8.53 16.5 23.3 3.07 4.53 4.33 0.133 0.0752 30 30 8.9 15.5 22.5 3.07 4.5 4.13 0.154 0.135 32.1 31 10.4 18.9 26.8 3.27 4.77 4.5 0.189 0.0955 31.9 34 7 13.7 20.3 3 4.32 3.78 0.0993 0.165 32.5 37 7.83 15.8 23.6 3.07 4.2 4.2 0.124 0.139 34.3 Table 35: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under 100 mM NaCl growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 36 Sorghum accessions, measured parameters under cold growth conditions Seed ID 19 20 21 22 23 24 25 26 20 6.5 11.2 3 3.9 4.73 0.0781 0.0681 28.6 22 8.77 15.9 3 4.13 5.33 0.154 0.108 30.3 26 10.4 18.4 3.5 4.63 5.43 0.189 0.163 27 27 6.8 12.2 3.17 4.17 5.5 0.112 0.0935 32.3 28 9.03 16 3.4 4.27 5.33 0.13 0.0835 28.3 29 9 14.6 3.2 4.23 5.07 0.165 0.114 29.9 30 7.97 14.6 3.13 4.2 4.5 0.152 0.137 32.5 31 9.17 17.3 3.07 4.3 5.4 0.15 0.127 28.6 34 6.5 13.4 3.07 4.17 5.37 0.112 0.108 31.7 37 7.23 13.9 3 4 5.18 0.141 0.139 29.6 Table 36: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under cold growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 37 Sorghum accessions, measured parameters under regular growth conditions Seed ID 27 28 29 30 31 32 33 34 20 7.47 15 3 4.17 5.33 0.101 0.0525 26.7 22 9.3 18.2 3.07 4.5 5.87 0.236 0.134 29.3 26 12.9 22.1 3.8 4.8 6.2 0.313 0.172 29.9 27 8.57 17.6 3.2 4.6 5.8 0.158 0.103 29.1 28 8.93 18.1 3.23 4.53 5.8 0.194 0.107 25 29 8.53 18.5 3.23 4.97 5.73 0.188 0.12 24.6 30 10.7 22.8 3.13 4.6 5.73 0.241 0.139 30.8 31 10.3 22 3.43 4.93 6 0.244 0.124 25.5 34 7.87 20 3 4.5 5.6 0.185 0.0994 32.9 37 8.77 21.8 3 4.57 6.07 0.242 0.115 33.5 Table 37: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under regular growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 38 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal, cold or salinity stress conditions across Sorghum accessions Exp. Correl. Exp. Correl. Gene Name R P value set Set ID Gene Name R P value set Set ID LNU202 0.71 3.35E−02 I 17 LNU84 0.76 4.81E−02 A 5 LNU202 0.74 1.47E−02 J 25 LNU168 0.70 3.43E−02 I 15 LNU84 0.76 4.73E−02 A 8 LNU84 0.77 4.19E−02 A 6 LNU280 0.86 2.80E−03 C 8 LNU84 0.76 4.92E−02 A 6 LNU84 0.88 8.76E−03 A 7 LNU168 0.95 1.13E−03 A 6 LNU84 0.77 4.16E−02 A 7 LNU168 0.94 1.82E−03 A 6 LNU280 0.81 7.50E−03 C 7 LNU278 0.91 4.12E−03 A 6 LNU84 0.75 2.05E−02 L 24 LNU84 0.73 2.50E−02 L 20 LNU84 0.71 3.31E−02 L 24 LNU84 0.85 1.62E−02 A 5 LNU202 0.77 1.43E−02 L 22 LNU84 0.81 2.61E−02 A 3 LNU202 0.77 1.56E−02 L 22 Table 38. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

TABLE 39 Correlation between the expression level of selected LNU homologous genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal, cold or salinity stress conditions across Sorghum accessions Exp. Correl. Exp. Correl. Gene Name R P value set Set ID Gene Name R P value Set Set ID LNU74_H173 0.96 8.89E−03 G 17 LNU271_H4 0.87 2.23E−03 L 22 LNU74_H173 0.89 4.39E−02 G 17 LNU265_H0 0.88 1.56E−03 L 22 LNU74_H173 0.96 8.89E−03 G 17 LNU265_H0 0.88 1.56E−03 L 22 LNU74_H173 0.89 4.39E−02 G 17 LNU67_H4 0.76 4.57E−02 A 5 LNU52_H6 0.73 2.48E−02 I 17 LNU74_H173 0.82 2.44E−02 A 5 LNU52_H6 0.72 2.75E−02 I 17 LNU74_H173 0.82 2.44E−02 A 5 LNU52_H6 0.73 2.48E−02 I 17 LNU13_H1 0.72 2.98E−02 C 5 LNU52_H6 0.72 2.75E−02 I 17 LNU13_H1 0.72 2.98E−02 C 5 LNU192_H3 0.82 6.46E−03 I 17 LNU45_H260 0.71 3.05E−02 C 5 LNU192_H3 0.74 2.18E−02 I 17 LNU35_H4 0.72 3.03E−02 C 5 LNU192_H3 0.82 6.46E−03 I 17 LNU35_H4 0.72 3.03E−02 C 5 LNU192_H3 0.74 2.18E−02 I 17 LNU19_H1 0.83 5.33E−03 I 15 LNU46_H60 0.76 1.85E−02 I 17 LNU263_H5 0.74 2.16E−02 I 15 LNU46_H60 0.76 1.85E−02 I 17 LNU263_H5 0.74 2.18E−02 I 15 LNU35_H4 0.81 7.57E−03 I 17 LNU263_H5 0.74 2.16E−02 I 15 LNU35_H4 0.81 7.57E−03 I 17 LNU263_H5 0.74 2.18E−02 I 15 LNU2_H4 0.72 1.93E−02 J 25 LNU45_H260 0.74 2.36E−02 C 6 LNU2_H??? 0.72 1.93E−02 J 25 LNU263_H5 0.70 3.53E−02 F 31 LNU2_H4 0.72 1.93E−02 J 25 LNU263_H5 0.70 3.53E−02 F 31 LNU48_H1 0.71 2.11E−02 J 25 LNU45_H260 0.99 6.05E−04 G 10 LNU48_H1 0.71 2.11E−02 J 25 LNU45_H260 0.98 3.25E−03 G 10 LNU52_H6 0.80 1.01E−02 L 25 LNU263_H5 0.75 2.10E−02 I 10 LNU52_H6 0.77 1.61E−02 L 25 LNU263_H5 0.74 2.18E−02 I 10 LNU52_H6 0.80 1.01E−02 L 25 LNU263_H5 0.75 2.10E−02 I 10 LNU52_H6 0.77 1.61E−02 L 25 LNU263_H5 0.74 2.18E−02 I 10 LNU48_H1 0.80 2.98E−02 A 8 LNU271_H4 0.93 2.36E−04 L 19 LNU48_H1 0.80 2.98E−02 A 8 LNU271_H4 0.84 4.40E−03 L 19 LNU74_H173 0.82 2.44E−02 A 8 LNU271_H4 0.93 2.36E−04 L 19 LNU74_H173 0.82 2.46E−02 A 8 LNU271_H4 0.84 4.40E−03 L 19 LNU74_H173 0.82 2.44E−02 A 8 LNU268_H2 0.82 2.40E−02 A 1 LNU74_H173 0.82 2.46E−02 A 8 LNU268_H2 0.77 4.31E−02 A 1 LNU89_H5 0.86 1.24E−02 A 8 LNU268_H2 0.82 2.40E−02 A 1 LNU89_H5 0.79 3.64E−02 A 8 LNU268_H2 0.77 4.31E−02 A 1 LNU89_H5 0.86 1.24E−02 A 8 LNU48_H1 0.85 1.47E−02 A 1 LNU89_H5 0.79 3.64E−02 A 8 LNU48_H1 0.85 1.47E−02 A 1 LNU121_H1 0.82 6.85E−03 C 8 LNU121_H1 0.74 2.38E−02 C 1 LNU121_H1 0.71 3.24E−02 C 8 LNU121_H1 0.74 2.38E−02 C 1 LNU121_H1 0.82 6.85E−03 C 8 LNU13_H1 0.70 3.39E−02 C 1 LNU121_H1 0.71 3.24E−02 C 8 LNU13_H1 0.70 3.42E−02 C 1 LNU13_H1 0.75 2.09E−02 C 8 LNU13_H1 0.70 3.39E−02 C 1 LNU13_H1 0.72 2.77E−02 C 8 LNU13_H1 0.70 3.42E−02 C 1 LNU13_H1 0.75 2.09E−02 C 8 LNU45_H260 0.84 4.75E−03 C 1 LNU13_H1 0.72 2.77E−02 C 8 LNU45_H260 0.80 9.40E−03 C 1 LNU67_H4 0.80 1.02E−02 C 8 LNU109_H2 0.78 1.40E−02 F 27 LNU67_H4 0.74 2.39E−02 C 8 LNU109_H2 0.76 1.83E−02 F 27 LNU71_H3 0.81 7.59E−03 C 8 LNU109_H2 0.78 1.40E−02 F 27 LNU71_H3 0.81 7.59E−03 C 8 LNU109_H2 0.76 1.83E−02 F 27 LNU45_H260 0.91 5.68E−04 C 8 LNU271_H4 0.93 2.36E−04 L 20 LNU45_H260 0.89 1.29E−03 C 8 LNU271_H4 0.86 3.12E−03 L 20 LNU268_H2 0.83 2.04E−02 A 7 LNU271_H4 0.93 2.36E−04 L 20 LNU268_H2 0.77 4.14E−02 A 7 LNU271_H4 0.86 3.12E−03 L 20 LNU268_H2 0.83 2.04E−02 A 7 LNU35_H4 0.73 2.49E−02 L 20 LNU268_H2 0.77 4.14E−02 A 7 LNU35_H4 0.73 2.49E−02 L 20 LNU48_H1 0.88 9.77E−03 A 7 LNU268_H2 0.82 2.41E−02 A 2 LNU48_H1 0.88 9.77E−03 A 7 LNU268_H2 0.77 4.45E−02 A 2 LNU89_H5 0.78 4.02E−02 A 7 LNU268_H2 0.82 2.41E−02 A 2 LNU89_H5 0.78 4.02E−02 A 7 LNU268_H2 0.77 4.45E−02 A 2 LNU46_H58 0.77 4.32E−02 A 7 LNU48_H1 0.89 6.82E−03 A 2 LNU46_H58 0.77 4.32E−02 A 7 LNU48_H1 0.89 6.82E−03 A 2 LNU121_H1 0.86 2.97E−03 C 7 LNU13_H1 0.86 2.89E−03 C 2 LNU121_H1 0.76 1.81E−02 C 7 LNU13_H1 0.85 3.66E−03 C 2 LNU121_H1 0.86 2.97E−03 C 7 LNU13_H1 0.86 2.89E−03 C 2 LNU121_H1 0.76 1.81E−02 C 7 LNU13_H1 0.85 3.66E−03 C 2 LNU13_H1 0.78 1.34E−02 C 7 LNU45_H260 0.86 3.18E−03 C 2 LNU13_H1 0.78 1.39E−02 C 7 LNU45_H260 0.80 1.01E−02 C 2 LNU13_H1 0.78 1.34E−02 C 7 LNU46_H58 0.76 1.81E−02 C 2 LNU13_H1 0.78 1.39E−02 C 7 LNU46_H58 0.74 2.25E−02 C 2 LNU67_H4 0.80 1.00E−02 C 7 LNU46_H58 0.76 1.81E−02 C 2 LNU67_H4 0.74 2.34E−02 C 7 LNU46_H58 0.74 2.25E−02 C 2 LNU45_H260 0.91 7.40E−04 C 7 LNU35_H4 0.88 1.98E−03 C 2 LNU45_H260 0.90 7.93E−04 C 7 LNU35_H4 0.88 1.98E−03 C 2 LNU35_H4 0.71 3.26E−02 C 7 LNU13_H1 0.86 3.30E−03 F 28 LNU35_H4 0.71 3.26E−02 C 7 LNU13_H1 0.84 4.94E−03 F 28 LNU45_H260 0.88 4.81E−02 G 16 LNU13_H1 0.86 3.30E−03 F 28 LNU67_H4 0.79 1.14E−02 I 16 LNU13_H1 0.84 4.94E−03 F 28 LNU67_H4 0.78 1.41E−02 I 16 LNU45_H260 0.99 2.20E−03 G 11 LNU263_H5 0.71 3.36E−02 I 16 LNU45_H260 0.95 1.24E−02 G 11 LNU263_H5 0.70 3.45E−02 I 16 LNU263_H5 0.90 9.67E−04 I 11 LNU263_H5 0.71 3.36E−02 I 16 LNU263_H5 0.90 1.10E−03 I 11 LNU263_H5 0.70 3.45E−02 I 16 LNU263_H5 0.90 9.67E−04 I 11 LNU271_H4 0.93 3.24E−04 L 24 LNU263_H5 0.90 1.10E−03 I 11 LNU271_H4 0.90 1.07E−03 L 24 LNU45_H260 0.89 4.59E−02 G 11 LNU271_H4 0.93 3.24E−04 L 24 LNU263_H5 0.94 1.36E−04 I 11 LNU271_H4 0.90 1.07E−03 L 24 LNU263_H5 0.94 1.51E−04 I 11 LNU35_H4 0.75 1.92E−02 L 24 LNU263_H5 0.94 1.36E−04 I 11 LNU35_H4 0.75 1.92E−02 L 24 LNU263_H5 0.94 1.51E−04 I 11 LNU45_H260 0.93 2.14E−02 G 13 LNU268_H2 0.84 1.77E−02 A 3 LNU263_H5 0.74 2.36E−02 I 13 LNU268_H2 0.78 3.66E−02 A 3 LNU263_H5 0.74 2.38E−02 I 13 LNU268_H2 0.84 1.77E−02 A 3 LNU263_H5 0.74 2.36E−02 I 13 LNU268_H2 0.78 3.66E−02 A 3 LNU263_H5 0.74 2.38E−02 I 13 LNU48_H1 0.84 1.74E−02 A 3 LNU267_H2 0.71 3.39E−02 L 21 LNU48_H1 0.84 1.74E−02 A 3 LNU267_H2 0.71 3.39E−02 L 21 LNU13_H1 0.85 3.76E−03 C 3 LNU265_H0 0.71 3.13E−02 L 21 LNU13_H1 0.84 4.64E−03 C 3 LNU265_H0 0.71 3.13E−02 L 21 LNU13_H1 0.85 3.76E−03 C 3 LNU73_H2 0.93 2.25E−03 A 4 LNU13_H1 0.84 4.64E−03 C 3 LNU223_H6 0.95 1.29E−03 A 4 LNU45_H260 0.76 1.68E−02 C 3 LNU223_H6 0.92 3.52E−03 A 4 LNU45_H260 0.70 3.44E−02 C 3 LNU223_H6 0.95 1.29E−03 A 4 LNU46_H58 0.80 9.90E−03 C 3 LNU223_H6 0.92 3.52E−03 A 4 LNU46_H58 0.78 1.28E−02 C 3 LNU7_H125 0.79 1.17E−02 C 4 LNU46_H58 0.80 9.90E−03 C 3 LNU7_H125 0.79 1.17E−02 C 4 LNU46_H58 0.78 1.28E−02 C 3 LNU7_H124 0.79 1.17E−02 C 4 LNU35_H4 0.88 1.56E−03 C 3 LNU71_H3 0.73 2.62E−02 C 4 LNU35_H4 0.88 1.56E−03 C 3 LNU71_H3 0.73 2.62E−02 C 4 LNU19_H1 0.83 5.26E−03 L 26 LNU7_H125 0.79 1.17E−02 C 4 LNU223_H6 0.82 7.43E−03 L 26 LNU7_H124 0.79 1.17E−02 C 4 LNU223_H6 0.82 7.43E−03 L 26 LNU7_H125 0.79 1.17E−02 C 4 LNU266_H0 0.82 2.29E−02 A 9 LNU109_H2 0.78 1.29E−02 F 29 LNU266_H0 0.77 4.09E−02 A 9 LNU109_H2 0.77 1.50E−02 F 29 LNU266_H0 0.82 2.29E−02 A 9 LNU109_H2 0.78 1.29E−02 F 29 LNU266_H0 0.77 4.09E−02 A 9 LNU109_H2 0.77 1.50E−02 F 29 LNU74_H173 0.84 1.86E−02 A 9 LNU263_H5 0.90 3.77E−02 G 14 LNU74_H173 0.83 1.95E−02 A 9 LNU263_H5 0.90 3.97E−02 G 14 LNU74_H173 0.84 1.86E−02 A 9 LNU263_H5 0.90 3.77E−02 G 14 LNU74_H173 0.83 1.95E−02 A 9 LNU263_H5 0.90 3.97E−02 G 14 LNU45_H260 0.79 3.54E−02 A 9 LNU263_H5 0.74 2.18E−02 I 14 LNU45_H258 0.77 4.27E−02 A 9 LNU263_H5 0.74 2.18E−02 I 14 LNU45_H258 0.77 4.27E−02 A 9 LNU263_H5 0.74 2.18E−02 I 14 LNU46_H60 0.79 3.44E−02 A 9 LNU263_H5 0.74 2.18E−02 I 14 LNU46_H60 0.79 3.44E−02 A 9 LNU266_H0 0.72 2.97E−02 L 22 LNU266_H0 0.95 7.83E−05 C 9 LNU266_H0 0.72 2.97E−02 L 22 LNU266_H0 0.91 6.80E−04 C 9 LNU271_H4 0.88 1.94E−03 L 22 LNU266_H0 0.95 7.83E−05 C 9 LNU271_H4 0.87 2.23E−03 L 22 LNU266_H0 0.91 6.80E−04 C 9 LNU271_H4 0.88 1.94E−03 L 22 LNU265_H0 0.82 6.68E−03 D 34 LNU265_H0 0.82 6.68E−03 D 34 Table 39. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

Example 9 Production of Maize Transcriptom and High Throughput Correlation Analysis with Yield and Nue Related Parameters Using 44K Maize Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a maize oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 44,000 maize genes and transcripts. In order to define correlations between the levels of RNA expression with yield and NUE components or vigor related parameters, various plant characteristics of 12 different maize hybrids were analyzed. Among them, 10 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Correlation of Maize Hybrids Across Ecotypes Grown Under Regular Growth Conditions

Experimental Procedures

12 Maize hybrids were grown in 3 repetitive plots, in field. Maize seeds were planted and plants were grown in the field using commercial fertilization and irrigation protocols. In order to define correlations between the levels of RNA expression with NUE and yield components or vigor related parameters, the 12 different maize hybrids were analyzed. Among them, 10 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Analyzed Sorghum tissues—All 10 selected maize hybrids were sample per each treatment. Plant tissues [Flag leaf, Flower meristem, Grain, Cobs, Internodes] growing under Normal conditions were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 40 below.

TABLE 40 Maize transcriptom expression sets Expression Set Set ID Maize field/Normal/flower meristem A Maize field/Normal/Ear B Maize field/Normal/Grain Distal C Maize field/Normal/Grain Basal D Maize field/Normal/Internode E Maize field/Normal/Leaf F Table 40: Provided are the maize transcriptom expression sets. Leaf = the leaf below the main ear; Flower meristem = Apical meristem following male flower initiation; Ear = the female flower at the anthesis day. Grain Distal = maize developing grains from the cob extreme area, Grain Basal = maize developing grains from the cob basal area; Internodes = internodes located above and below the main ear in the plant.

The following parameters were collected using digital imaging system:

Grain Area (cm²)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weight, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain Length and Grain width (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weight, photographed and images were processed using the below described image processing system. The sum of grain lengths/or width (longest axis) was measured from those images and was divided by the number of grains.

Ear Area (cm²)—At the end of the growing period 5 ears were, photographed and images were processed using the below described image processing system. The Ear area was measured from those images and was divided by the number of Ears.

Ear Length and Ear Width (cm) At the end of the growing period 5 ears were, photographed and images were processed using the below described image processing system. The Ear length and width (longest axis) was measured from those images and was divided by the number of ears.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 6 plants per plot or by measuring the parameter across all the plants within the plot.

Normalized Grain Weight per plant (gr.)—At the end of the experiment all ears from plots within blocks A-C were collected. 6 ears were separately threshed and grains were weighted, all additional ears were threshed together and weighted as well. The average grain weight per ear was calculated by dividing the total grain weight by number of total ears per plot (based on plot). In case of 6 ears, the total grains weight of 6 ears was divided by 6.

Ear FW (gr.)—At the end of the experiment (when ears were harvested) total and 6 selected ears per plots within blocks A-C were collected separately. The plants with (total and 6) were weighted (gr.) separately and the average ear per plant was calculated for total (Ear FW per plot) and for 6 (Ear FW per plant).

Plant height and Ear height—Plants were characterized for height at harvesting. In each measure, 6 plants were measured for their height using a measuring tape. Height was measured from ground level to top of the plant below the tassel. Ear height was measured from the ground level to the place were the main ear is located

Leaf number per plant—Plants were characterized for leaf number during growing period at 5 time points. In each measure, plants were measured for their leaf number by counting all the leaves of 3 selected plants per plot.

Relative Growth Rate was calculated using Formulas IX and X (described above).

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot. Data were taken after 46 and 54 days after sowing (DPS) Dry weight per plant—At the end of the experiment (when Inflorescence were dry) all vegetative material from plots within blocks A-C were collected.

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours;

Harvest Index (HI) (Maize)—The harvest index was calculated using Formula XII.

Harvest Index=Average grain dry weight per Ear/(Average vegetative dry weight per Ear+Average Ear dry weight)  Formula XII:

Percent Filled Ear [%]—it was calculated as the percentage of the Ear area with grains out of the total ear.

Cob diameter [cm]—The diameter of the cob without grains was measured using a ruler.

Kernel Row Number per Ear—The number of rows in each ear was counted.

Experimental Results

12 different maize hybrids were grown and characterized for different parameters: The average for each of the measured parameter was calculated using the JMP software (Tables 42-43) and a subsequent correlation analysis was performed (Tables 44 and 45). Results were then integrated to the database.

TABLE 41 Maize correlated parameters (vectors) Correlations Correlation ID SPAD 54DPS [SPAD units] 1 SPAD 46DPS [SPAD units] 2 Growth Rate Leaf Num 3 Plant Height per Plot [cm] 4 Ear Height [cm] 5 Leaf Number per Plant [number] 6 Ear Length [cm] 7 Percent Filled Ear [%] 8 Cob Diameter [mm] 9 Kernel Row Number per Ear [number] 10 DW per Plant [gr] 11 Ear FW per Plant gr] 12 Normalized Grain Weight per plant [gr] 13 Ears FW per plot [gr] 14 Normalized Grain Weight per plot [gr] 15 Ear Area [cm2] 16 Ear Width [cm] 17 Grain Area [cm2] 18 Grain Length [cm] 19 Grain Width [cm] 20 Table 41. SPAD 46DPS and SPAD 54DPS: Chlorophyl level after 46 and 54 days after sowing (DPS).

TABLE 42 Measured parameters in Maize accessions under normal conditions Seed ID 1 2 3 4 5 6 7 8 9 10 11 Line 1 54.8 55.3 0.306 287 135 11.9 20.9 80.4 28.7 16.2 656 Line 2 54.3 51.7 0.283 278 135 12 19.7 80.6 29 16.2 658 Line 3 57.2 56.4 0.221 270 116 8.4 19.1 94.3 23.8 15 472 Line 4 56 53.5 0.281 275 132 11.7 20.5 82.1 28.1 16.2 641 Line 5 59.7 55.2 0.269 238 114 11.8 21.3 92.7 25.7 15.9 581 Line 6 59.1 59.4 0.244 225 94.3 12.3 18.2 82.8 25.8 15.2 569 Line 7 58 58.5 0.244 264 121 12.4 19 73.2 26.4 16 511 Line 8 60.4 55.9 0.266 252 108 12.2 18.6 81.1 25.2 14.8 544 Line 9 54.8 53 Line 10 53.3 50 Line 11 61.1 59.7 0.301 278 112 12.6 21.7 91.6 26.7 15.4 522 Line 12 51.4 53.9 0.194 164 60.4 9.28 16.7 81.1 14.3 574 141 Table 42. Provided are the values of each of the parameters (as described above) measured in maize accessions (Seed ID) under regular growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 43 Additional measured parameters in Maize accessions under regular growth conditions Seed ID 12 13 14 15 16 17 18 19 20 Line 1 272 157 280 140 91.6 5.73 0.806 1.23 0.824 Line 2 246 141 278 154 85.1 5.58 0.753 1.17 0.81 Line 3 190 129 190 121 77.9 5.1 0.674 1.07 0.794 Line 4 262 154 288 152 90.5 5.67 0.755 1.18 0.803 Line 5 264 177 248 159 96 5.53 0.766 1.2 0.803 Line 6 178 120 176 117 72.4 5.23 0.713 1.12 0.803 Line 7 189 120 192 123 74 5.22 0.714 1.14 0.791 Line 8 197 134 205 131 76.5 5.33 0.753 1.13 0.837 Line 9 Line 10 Line 11 261 173 264 171 95.4 5.58 0.762 1.18 0.812 Line 12 54.3 143 40.8 55.2 4.12 0.796 0.921 0.675 Table 43. Provided are the values of each of the parameters (as described above) measured in maize accessions (Seed ID) under regular growth conditions. Growth conditions are specified in the experimental procedure section.

Table 44 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under normal across maize accessions Gene P Exp. Correl. Gene P Exp. Correl. Name R value set Set ID Name R value set Set ID LNU267 0.81 2.77E−02 F 8 LNU265 0.78 3.99 E−02 B 17 LNU113 0.76 2.86E−02 C 9 LNU265 0.76 4.86E−02 B 5 LNU113 0.76 2.88E−02 C 9 LNU265 0.76 4.98E−02 B 18 LNU265 0.89 7.21E−03 B 8 LNU265 0.72 4.32E−02 C 15 LNU265 0.80 3.16E−02 B 20 LNU98  0.78 3.84E−02 E 11 LNU265 0.78 7.51E−03 F 2 Table 44. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

TABLE 45 Correlation between the expression level of selected LNU homologous genes of some embodiments of the invention in various tissues and the phenotypic performance under normal across maize accessions Correl. Correl. Gene P Exp. Set Gene P Exp. Set Name R value Set ID Name R value Set ID LNU74_H112 0.84 1.67E−02 B 11 LNU34_H0 0.82 2.26E−02 F 3 LNU46_H34 0.79 3.59E−02 B 11 LNU34_H0 0.79 3.36E−02 F 3 LNU51_H1 0.76 4.84E−02 B 3 LNU34_H0 0.79 3.29E−02 E 12 LNU52_H5 0.86 1.37E−02 B 18 LNU34_H0 0.79 3.57E−02 F 3 LNU45_H173 0.79 3.53E−02 B 16 LNU115_H0 0.81 2.74E−02 B 6 LNU64_H1 0.85 1.53E−02 B 18 LNU35_H2 0.76 4.85E−02 E 12 LNU64_H1 0.85 1.54E−02 B 18 LNU74_H111 0.71 2.23E−02 F 12 LNU74_H118 0.95 3.98E−03 B 16 LNU13_H0 0.87 1.13E−02 F 12 LNU278_H2 0.84 1.89E−02 B 11 LNU45_H173 0.71 4.78E−02 E 19 LNU216_H0 0.96 2.60E−03 B 11 LNU51_H1 0.88 8.90E−03 B 6 LNU74_H110 0.84 1.83E−02 B 18 LNU74_H109 0.81 2.65E−02 B 6 LNU74_H118 0.94 5.44E−03 B 16 LNU45_H173 0.78 3.79E−02 B 6 LNU34_H0 0.76 4.59E−02 B 18 LNU279_H2 0.92 1.08E−03 C 9 LNU45_H173 0.81 4.97E−02 B 16 LNU7_H89 0.85 3.26E−02 B 6 LNU45_H173 0.77 4.28E−02 B 18 LNU52_H5 0.87 9.94E−03 B 8 LNU35_H2 0.90 5.70E−03 B 18 LNU74_H110 0.95 9.33E−04 B 8 LNU271_H3 0.81 1.46E−02 C 16 LNU7_H89 0.84 3.45E−02 B 6 LNU51_H1 0.89 1.71E−02 B 11 LNU7_H89 0.85 3.26E−02 B 6 LNU271_H3 0.76 2.73E−02 C 16 LNU7_H89 0.84 3.45E−02 B 6 LNU64_H1 0.85 1.53E−02 B 18 LNU115_H0 0.78 1.33E−02 E 6 LNU278_H2 0.90 1.50E−02 B 11 LNU74_H110 0.91 4.94E−03 B 8 LNU64_H1 0.85 1.54E−02 B 18 LNU279_H1 0.74 3.49E−02 C 9 LNU13_H0 0.77 2.47E−02 C 11 LNU34_H0 0.85 7.43E−03 C 9 LNU64_H1 0.77 4.40E−02 B 3 LNU34_H0 0.83 1.01E−02 C 9 LNU64_H1 0.76 4.82E−02 B 3 LNU52_H4 0.78 1.26E−02 E 6 LNU13_H0 0.74 3.48E−02 C 11 LNU7_H89 0.78 1.40E−02 E 6 LNU13_H0 0.74 3.53E−02 C 11 LNU7_H89 0.71 3.34E−02 E 6 LNU52_H5 0.76 2.93E−02 C 11 LNU34_H0 0.81 1.54E−02 C 9 LNU52_H5 0.73 4.07E−02 C 11 LNU7_H89 0.70 3.54E−02 E 6 LNU216_H1 0.88 8.39E−03 E 16 LNU7_H88 0.83 6.01E−03 E 6 LNU52_H5 0.86 1.39E−02 E 16 LNU74_H111 0.76 4.89E−02 F 19 LNU52_H4 0.71 4.92E−02 C 11 LNU74_H110 0.83 2.00E−02 B 8 LNU71_H0 0.78 2.30E−02 C 11 LNU7_H88 0.79 1.06E−02 E 6 LNU279_H2 0.77 4.29E−02 E 16 8 LNU7_H8 0.78 1.28E−02 E 6 LNU34_H0 0.95 8.43E−04 E 16 LNU74_H110 0.81 2.85E−02 B 8 LNU74_H118 0.84 3.81E−02 B 18 LNU74_H110 0.77 4.51E−02 B 8 LNU74_H111 0.71 4.86E−02 E 16 LNU52_H5 0.92 3.01E−03 B 20 LNU71_H0 0.75 3.07E−02 C 11 LNU64_H1 0.87 1.03E−02 B 20 LNU271_H3 0.74 3.77E−02 C 18 LNU7_H87 0.71 3.37E−02 E 6 LNU271_H2 0.71 4.67E−02 C 11 LNU64_H1 0 .87 1.18E−02 B 20 LNU13_H0 0.78 3.87E−02 F 16 LNU74_H118 0.78 1.39E−02 E 6 LNU74_H111 0.77 4.23E−02 F 16 LNU74_H110 0.91 4.62E−03 B 20 LNU7_H87 0.84 1.84E−02 B 14 LNU74_H112 0.91 4.94E−03 B 8 LNU271_H3 0.88 3.84E−03 C 11 LNU74_H118 0.74 2.14E−02 E 6 LNU34_H0 0.73 3.96E−02 C 18 LNU74_H112 0.77 4.51E−02 B 8 LNU115_H0 0.77 1.54E−02 E 18 LNU74_H118 0.74 2.22E−02 E 6 LNU74_H118 0.74 2.38E−02 E 18 LNU74_H116 0.78 1.39E−02 E 6 LNU7_H87 0.76 4.59E−02 B 14 LNU74_H110 0.78 1.39E−02 E 6 LNU271_H3 0.78 2.29E−02 C 11 LNU74_H110 0.73 2.44E−02 E 6 LNU74_H118 0.72 2.83E−02 E 18 LNU74_H116 0.78 1.39E−02 E 6 LNU74_H109 0.82 2.31E−02 B 3 LNU74_H109 0.76 1.86E−02 E 6 LNU279_H2 0.86 6.55E−03 C 11 LNU74_H109 0.73 2.54E−02 E 6 LNU7_H8 0.76 4.79E−02 B 14 LNU74_H113 0.78 1.39E−02 E 6 LNU34_H0 0.82 1.35E−02 C 11 LNU74_H112 0.78 1.39E−02 E 6 LNU85_H2 0.71 3.12E−02 E 18 LNU74_H112 0.73 2.44E−02 E 6 LNU7_H87 0.84 1.84E−02 B 14 LNU74_H110 0.77 4.18E−02 B 20 LNU34_H0 0.81 1.51E−02 C 11 LNU74_H110 0.77 4.27E−02 B 20 LNU34_H0 0.78 2.29E−02 C 11 LNU74_H110 0.77 4.39E−02 B 20 LNU271_H3 0.84 4.49E−03 E 11 LNU7_H89 0.78 1.40E−02 E 6 LNU271_H3 0.77 1.58E−02 E 11 LNU74_H112 0.77 4.39E−02 B 20 LNU7_H87 0.76 4.59E−02 B 14 LNU7_H89 0.71 3.34E−02 E 6 LNU7_H87 0.76 4.79E−02 B 14 LNU7_H89 0.70 3.54E−02 E 6 LNU69_H2 0.76 4.75E−02 E 11 LNU7_H88 0.83 6.01E−03 E 6 LNU74_H111 0.82 2.44E−02 E 11 LNU7_H88 0.79 1.06E−02 E 6 LNU45_H173 0.87 1.10E−02 B 14 LNU7_H88 0.78 1.28E−02 E 6 LNU279_H1 0.88 2.09E−02 B 10 LNU7_H87 0.71 3.37E−02 E 6 LNU45_H173 0.85 1.45E−02 B 14 LNU45_H169 0.80 1.01E−02 E 6 LNU45_H173 0.84 1.78E−02 B 14 LNU45_H169 0.78 1.32E−02 E 6 LNU76_H37 0.76 4.93E−02 E 18 LNU45_H168 0.82 6.36E−03 E 6 LNU34_H0 0.84 3.62E−02 B 9 LNU51_H1 0.80 3.24E−02 E 6 LNU74_H111 0.76 4.94E−02 E 11 LNU34_H0 0.92 2.97E−03 B 8 LNU76_H38 0.76 4.93E−02 E 18 LNU279_H2 0.83 1.99E−02 E 6 LNU74_H118 0.96 2.95E−03 B 14 LNU34_H0 0.75 3.22E−02 E 6 LNU74_H118 0.94 5.02E−03 B 14 LNU34_H0 0.86 1.41E−02 B 20 LNU46_H35 0.83 1.99E−02 E 11 LNU34_H0 0.81 2.64E−02 B 20 LNU45_H173 0.89 1.70E−02 B 14 LNU34_H0 0.76 4.86E−02 B 20 LNU45_H173 0.89 1.77E−02 B 14 LNU35_H2 0.93 2.72E−03 B 20 LNU279_H2 0.84 1.76E−02 E 18 LNU64_H1 0.87 1.03E−02 B 20 LNU34_H0 0.89 6.53E−03 E 18 LNU271_H3 0.88 3.49E−03 E 9 LNU45_H173 0.92 3.19E−03 B 3 LNU64_H1 0.87 1.18E−02 B 20 LNU48_H0 0.75 1.31E−02 F 11 LNU271_H3 0.80 1.78E−02 E 9 LNU115_H0 0.83 2.14E−02 F 11 LNU17_H1 0.84 3.53E−02 B 20 LNU45_H173 0.90 1.54E−02 B 9 LNU2_H3 0.81 4.88E−02 B 20 LNU45_H173 0.83 3.90E−02 B 14 LNU48_H0 0.93 7.37E−03 B 20 LNU35_H2 0.88 2.05E−02 B 14 LNU25_H0 0.87 2.57E−02 B 20 LNU271_H3 0.88 3.73E−03 C 14 LNU223_H3 0.74 3.56E−02 E 9 LNU271_H3 0.79 1.87E−02 C 14 LNU25_H0 0.85 3.39E−02 B 20 LNU35_H2 0.79 3.62E−02 E 18 LNU279_H0 0.87 2.42E−02 B 20 LNU279_H2 0.78 2.30E−02 C 14 LNU279_H0 0.86 2.94E−02 B 20 LNU216_H1 0.94 1.76E−03 E 14 LNU279_H2 0.92 8.63E−03 B 20 LNU52_H5 0.76 4.97E−02 E 14 LNU34_H0 0.89 6.68E−03 B 8 LNU34_H0 0.88 8.34E−03 E 14 LNU279_H1 0.92 8.63E−03 B 20 LNU13_H0 0.85 1.65E−02 F 14 LNU34_H0 0.81 2.75E−02 B 8 LNU45_H173 0.78 3.87E−02 B 3 LNU239_H6 0.75 3.13E−02 C 20 LNU74_H111 0.81 2.78E−02 F 18 LNU35_H2 0.94 1.48E−03 B 8 LNU45_H173 0.77 4.38E−02 B 3 LNU85_H2 0.84 1.89E−02 B 8 LNU84_H0 0.76 4.64E−02 F 14 LNU239_H6 0.75 3.17E−02 C 20 LNU84_H0 0.76 4.64E−02 F 14 LNU85_H2 0.78 1.38E−02 E 20 LNU64_H1 0.87 1.14E−02 B 5 LNU85_H2 0.77 4.20E−02 B 8 LNU64_H1 0.81 2.84E−02 B 5 LNU85_H2 0.76 1.72E−02 E 20 LNU7_H87 0.79 3.46E−02 B 5 LNU76_H37 0.78 3.68E−02 E 20 LNU35_H2 0.76 4.90E−02 F 18 LNU19_H0 0.82 4.69E−02 B 8 LNU52_H5 0.79 3.62E−02 B 19 LNU279_H2 0.77 4.33E−02 E 20 LNU7_H87 0.76 4.94E−02 B 5 LNU74_H111 0.85 3.33E−02 B 8 LNU64_H1 0.78 3.97E−02 B 19 LNU45_H169 0.91 1.17E−02 B 8 LNU7_H87 0.79 3.46E−02 B 5 LNU239_H5 0.90 1.43E−02 B 8 LNU7_H87 0.76 4.94E−02 B 5 LNU34_H0 0.77 4.20E−02 E 20 LNU35_H2 0.78 3.76E−02 B 3 LNU64_H1 0.70 3.41E−02 E 8 LNU34_H0 0.80 2.99E−02 B 5 LNU35_H2 0.78 3.92E−02 E 20 LNU34_H0 0.77 4.31E−02 B 5 LNU153_H3 0.77 4.26E−02 E 20 LNU35_H2 0.77 4.28E−02 B 5 LNU19_H0 0.75 3.05E−02 E 20 LNU64_H1 0.87 1.14E−02 B 5 LNU216_H0 0.80 1.78E−02 E 20 LNU64_H1 0.81 2.84E−02 B 5 LNU67_H2 0.86 6.40E−03 E 20 LNU64_H1 0.78 4.04E−02 B 19 LNU271_H2 0.87 4.49E−03 E 20 LNU35_H2 0.85 3.04E−02 B 5 LNU279_H2 0.89 3.36E−03 E 20 LNU74_H110 0.75 4.99E−02 B 19 LNU279_H2 0.72 4.47E−02 E 20 LNU13_H0 0.72 4.54E−02 C 5 LNU279_H1 0.72 4.47E−02 E 20 LNU45_H173 0.82 2.26E−02 B 19 LNU223_H4 0.72 1.91E−02 F 20 LNU35_H2 0.84 1.78E−02 B 19 LNU76_H37 0.70 2.35E−02 F 6 LNU279_H2 0.90 2.37E−03 C 5 LNU74_H111 0.81 2.70E−02 F 20 LNU46_H34 0.81 1.46E−02 C 5 LNU35_H2 0.79 3.57E−02 F 20 LNU34_H0 0.82 2.36E−02 E 5 LNU52_H5 0.76 4.89E−02 B 15 LNU64_H1 0.78 3.97E−02 B 19 LNU74_H110 0.80 3.12E−02 B 15 LNU35_H2 0.93 2.24E−03 E 5 LNU222_H2 0.74 2.37E−02 E 8 LNU64_H1 0.78 4.04E−02 B 19 LNU45_H173 0.76 4.93E−02 B 15 LNU74_H111 0.78 4.02E−02 F 5 LNU64_H1 0.70 3.41E−02 E 8 LNU64_H1 0.77 4.40E−02 B 3 LNU35_H2 0.76 4.79E−02 B 15 LNU64_H1 0.76 4.82E−02 B 3 LNU52_H5 0.79 3.46E−02 E 8 LNU74_H118 0.94 4.87E−03 B 19 LNU74_H118 0.91 1.27E−02 B 15 LNU35_H2 0.78 3.87E−02 F 5 LNU74_H118 0.90 1.51E−02 B 15 LNU7_H87 0.77 4.50E−02 B 7 LNU45_H169 0.86 2.93E−02 B 15 LNU74_H118 0.93 6.77E−03 B 19 LNU34_H0 0.77 4.47E−02 E 8 LNU7_H87 0.77 4.50E−02 B 7 LNU45_H169 0.84 3.68E−02 B 15 LNU45_H173 0.88 2.14E−02 B 19 LNU45_H168 0.88 2.11E−02 B 15 LNU45_H173 0.76 4.71E−02 B 7 LNU35_H2 0.80 2.92E−02 E 8 LNU74_H118 0.88 2.01E−02 B 7 LNU216_H1 0.78 2.36E−02 E 8 LNU74_H118 0.88 2.09E−02 B 7 LNU216_H0 0.73 4.00E−02 C 15 LNU45_H168 0.88 2.20E−02 B 7 LNU271_H3 0.72 4.46E−02 C 15 LNU271_H3 0.80 1.70E−02 C 7 LNU51_H1 0.71 4.94E−02 E 8 LNU271_H3 0.76 2.93E−02 C 7 LNU52_H5 0.75 3.18E−02 E 8 LNU216_H1 0.93 2.42E−03 E 7 LNU76_H38 0.70 2.35E−02 F 6 LNU45_H173 0.87 2.25E−02 B 19 LNU271_H3 0.71 4.85E−02 C 15 LNU52_H5 0.87 1.07E−02 E 7 LNU216_H1 0.79 3.42E−02 E 15 LNU279_H2 0.76 4.74E−02 E 7 LNU69_H2 0.71 5.00E−02 E 8 LNU34_H0 0.92 3.25E−03 E 7 LNU52_H5 0.87 1.18E−02 E 15 LNU45_H173 0.83 4.10E−02 B 19 LNU45_H170 0.72 4.38E−02 E 8 LNU45_H173 0.81 1.49E−02 E 7 LNU76_H37 0.77 4.30E−02 E 15 LNU45_H173 0.74 3.39E−02 E 7 LNU45_H173 0.72 4.38E−02 E 8 LNU45_H173 0.73 4.07E−02 E 7 LNU76_H38 0.77 4.30E−02 E 15 LNU13_H0 0.84 1.76E−02 F 7 LNU74_H110 0.79 3.47E−02 F 8 LNU52_H5 0.77 4.42E−02 B 17 LNU74_H110 0.76 4.66E−02 F 8 LNU64_H1 0.85 1.52E−02 B 17 LNU279_H2 0.81 2.68E−02 E 15 LNU64_H1 0.84 1.84E−02 B 17 LNU34_H0 0.97 2.32E−04 E 15 LNU74_H110 0.80 3.12E−02 B 17 LNU45_H173 0.74 3.52E−02 E 15 LNU74_H118 0.87 2.34E−02 B 3 LNU74_H111 0.81 2.82E−02 F 15 LNU34_H0 0.77 4.46E−02 B 17 LNU35_H2 0.78 3.75E−02 F 15 LNU74_H118 0.85 3.35E−02 B 3 LNU52_H5 0.77 4.49E−02 B 13 LNU35_H2 0.91 1.16E−02 B 19 LNU64_H1 0.78 4.03E−02 B 13 LNU45_H173 0.81 2.74E−02 B 17 LNU74_H111 0.88 8.99E−03 F 8 LNU35_H2 0.89 6.82E−03 B 17 LNU74_H110 0.84 1.89E−02 B 13 LNU64_H1 0.85 1.52E−02 B 17 LNU74_H111 0.78 3.68E−02 F 8 LNU7_H87 0.77 2.69E−02 C 19 LNU35_H2 0.88 9.78E−03 F 8 LNU7_H87 0.75 3.33E−02 C 19 LNU45_H173 0.78 3.75E−02 B 13 LNU64_H1 0.84 1.84E−02 B 17 LNU45_H173 0.79 3.34E−02 B 10 LNU5l_H1 0.82 4.40E−02 B 17 LNU35_H2 0.84 1.89E−02 B 13 LNU74_H118 0.94 5.68E−03 B 17 LNU7_H89 0.82 4.69E−02 B 10 LNU7_H87 0.77 2.69E−02 C 19 LNU64_H1 0.78 4.03E−02 B 13 LNU7_H87 0.75 3.33E−02 C 19 LNU74_H110 0.94 5.95E−03 B 10 LNU271_H3 0.87 4.80E−03 C 19 LNU74_H112 0.94 5.95E−03 B 10 LNU271_H3 0.82 1.30E−02 C 19 LNU74_H118 0.89 1.81E−02 B 13 LNU74_H118 0.92 8.82E−03 B 17 LNU74_H118 0.87 2.55E−02 B 13 LNU45_H173 0.93 7.66E−03 B 17 LNU216_H0 0.73 3.89E−02 C 13 LNU45_H173 0.92 8.24E−03 B 17 LNU71_H0 0.75 3.33E−02 C 13 LNU45_H173 0.87 2.30E−02 B 17 LNU271_H3 0.81 1.58E−02 C 13 LNU35_H2 0.85 3.01E−02 B 17 LNU7_H89 0.82 4.69E−02 B 10 LNU13_H0 0.71 4.87E−02 C 17 LNU271_H3 0.86 6.62E−03 C 10 LNU7_H87 0.72 4.19E−02 C 17 LNU271_H3 0.78 2.12E−02 C 10 LNU71_H0 0.77 2.47E−02 C 17 LNU271_H3 0.78 2.34E−02 C 13 LNU71_H0 0.75 3.28E−02 C 17 LNU279_H2 0.77 2.46E−02 C 10 LNU7_H87 0.72 4.19E−02 C 17 LNU216_H1 0.81 2.65E−02 E 10 LNU271_H3 0.89 2.99E−03 C 17 LNU52_H5 0.87 1.14E−02 E 13 LNU271_H3 0.77 2.46E−02 C 17 LNU279_H2 0.86 1.37E−02 E 13 LNU279_H2 0.87 4.77E−03 C 17 LNU48_H0 0.72 2.73E−02 F 9 LNU34_H0 0.72 4.57E−02 C 17 LNU64_H1 0.84 1.85E−02 B 4 LNU115_H0 0.71 3.22E−02 E 17 LNU7_H89 0.73 1.58E−02 F 2 LNU115_H0 0.79 1.10E−02 E 19 LNU74_H110 0.73 1.55E−02 F 2 LNU74_H118 0.72 2.72E−02 E 19 LNU84_H0 0.77 4.38E−02 E 10 LNU52_H5 0.77 4.15E−02 E 17 LNU74_H111 0.74 2.28E−02 F 9 LNU279_H2 0.82 2.45E−02 E 17 LNU34_H0 0.84 1.72E−02 E 10 LNU34_H0 0.92 3.49E−03 E 17 LNU74_H111 0.72 3.03E−02 F 9 LNU74_H118 0.71 3.14E−02 E 19 LNU64_H1 0.77 4.22E−02 B 4 LNU35_H2 0.86 1.39E−02 E 17 LNU74_H112 0.73 1.55E−02 F 2 LNU74_H111 0.83 2.11E−02 F 17 LNU74_H110 0.87 1.17E−02 B 4 LNU35_H2 0.77 4.11E−02 F 17 LNU74_H110 0.76 4.57E−02 B 4 LNU76_H37 0.76 4.52E−02 E 19 LNU7_H89 0.73 1.58E−02 F 2 LNU7_H87 0.91 4.98E−03 B 12 LNU45_H169 0.72 2.73E−02 F 9 LNU7_H87 0.86 1.38E−02 B 12 LNU280_H1 0.78 8.26E−03 F 2 LNU7_H87 0.83 1.96E−02 B 12 LNU34_H0 0.95 9.71E−04 E 13 LNU7_H87 0.91 4.98E−03 B 12 LNU34_H0 0.82 2.41E−02 B 4 LNU7_H87 0.86 1.38E−02 B 12 LNU115_H0 0.84 3.61E−02 F 9 LNU13_H0 0.82 1.27E−02 C 9 LNU34_H0 0.80 3.12E−02 B 4 LNU13_H0 0.79 1.89E−02 C 9 LNU35_H2 0.83 2.10E−02 B 4 LNU13_H0 0.79 1.91E−02 C 9 LNU85_H2 0.77 4.39E−02 B 4 LNU13_H0 0.77 2.44E−02 C 3 LNU84_H0 0.77 4.38E−02 E 10 LNU7_H87 0.83 1.96E−02 B 12 LNU51_H1 0.77 4.46E−02 F 6 LNU13_H0 0.77 2.56E−02 C 3 LNU74_H111 0.74 1.41E−02 F 10 LNU13_H0 0.76 2.80E−02 C 3 LNU74_H111 0.72 1.93E−02 F 10 LNU45_H173 0.91 4.15E−03 B 12 LNU64_H1 0.84 1.85E−02 B 4 LNU45_H173 0.91 4.63E−03 B 12 LNU84_H0 0.79 3.42E−02 F 10 LNU45_H173 0.88 9.87E−03 B 12 LNU64_H1 0.77 4.22E−02 B 4 LNU74_H118 0.91 1.15E−02 B 12 LNU35_H2 0.94 5.10E−03 B 4 LNU74_H118 0.89 1.69E−02 B 12 LNU7_H89 0.81 4.97E−02 F 9 LNU45_H173 0.92 9.33E−03 B 12 LNU279_H2 0.78 2.37E−02 C 4 LNU45_H173 0.91 1.10E−02 B 12 LNU84_H0 0.79 3.42E−02 F 10 LNU52_H5 0.83 1.06E−02 C 9 LNU19_H0 0.91 1.21E−02 B 8 LNU52_H5 0.83 1.10E−02 C 9 LNU46_H34 0.82 1.23E−02 C 4 LNU52_H5 0.77 2.55E−02 C 3 LNU85_H2 0.72 3.04E−02 E 4 LNU45_H173 0.87 2.48E−02 B 12 LNU45_H169 0.90 1.43E−02 B 8 LNU52_H4 0.78 2.19E−02 C 3 LNU52_H5 0.83 2.02E−02 E 4 LNU74_H111 0.72 4.46E−02 C 3 LNU32_H0 0.83 1.97E−02 E 4 LNU52_H4 0.75 3.11E−02 C 9 LNU45_H169 0.89 1.83E−02 B 8 LNU271_H2 0.72 4.57E−02 C 3 LNU67_H2 0.78 3.74E−02 F 6 LNU76_H38 0.76 4.52E−02 E 19 LNU35_H2 0.78 3.76E−02 E 13 LNU279_H2 0.83 2.06E−02 E 19 LNU64_H1 0.73 1.70E−02 F 13 LNU35_H2 0.90 1.55E−02 B 12 LNU32_H0 0.83 2.16E−02 E 4 LNU271_H3 0.79 1.99E−02 C 3 LNU45_H169 0.88 2.01E−02 B 8 LNU13_H0 0.72 4.60E−02 C 12 LNU74_H111 0.78 3.76E−02 F 1 LNU279_H2 0.85 7.52E−03 C 3 LNU45_H168 0.82 4.55E−02 B 8 LNU34_H0 0.81 1.44E−02 C 3 LNU280_H1 0.75 3.04E−02 C 8 LNU71_H0 0.77 2.60E−02 C 12 LNU64_H1 0.73 1.70E−02 F 13 LNU34_H0 0.75 3.24E−02 C 3 LNU7_H89 0.81 4.97E−02 F 9 LNU34_H0 0.71 4.66E−02 C 3 LNU52_H5 0.76 4.59E−02 E 8 LNU74_H111 0.72 4.32E−02 C 9 LNU34_H0 0.82 2.30E−02 F 6 LNU115_H0 0.82 7.10E−03 E 3 LNU34_H0 0.77 4.48E−02 E 4 LNU34_H0 0.94 1.70E−03 E 19 LNU34_H0 0.77 4.23E−02 F 6 LNU115_H0 0.78 2.16E−02 E 19 LNU34_H0 0.76 4.74E−02 F 6 LNU71_H0 0.75 3.37E−02 C 12 LNU35_H2 0.92 3.67E−03 E 4 LNU271_H2 0.77 2.49E−02 C 9 LNU74_H110 0.83 2.20E−02 F 4 LNU74_H118 0.72 2.92E−02 E 3 LNU76_H37 0.76 2.84E−02 E 8 LNU74_H118 0.70 3.55E−02 E 3 LNU74_H110 0.76 4.91E−02 F 4 LNU271_H3 0.85 7.04E−03 C 12 LNU45_H173 1.00 2.63E−05 F 9 LNU279_H2 0.95 1.30E−03 E 3 LNU45_H173 0.99 9.74E−05 F 9 LNU34_H0 0.80 3.18E−02 E 3 LNU45_H173 0.97 1.64E−03 F 9 LNU74_H110 0.85 7.58E−03 E 19 LNU74_H111 0.93 2.57E−03 F 4 LNU271_H3 0.72 4.44E−02 C 12 LNU76_H38 0.76 2.84E−02 E 8 LNU13_H0 0.80 3.08E−02 F 3 LNU74_H111 0.87 1.14E−02 F 4 LNU271_H3 0.82 1.26E−02 C 9 LNU74_H111 0.87 1.12E−02 F 13 LNU74_H112 0.85 7.58E−03 E 19 LNU35_H2 0.94 1.58E−03 F 4 LNU279_H2 0.92 1.15E−03 C 12 LNU2_H3 0.81 2.74E−02 F 8 LNU74_H111 0.81 2.57E−02 F 3 LNU271_H3 0.82 2.53E−02 F 8 LNU216_H1 0.89 7.80E−03 E 12 LNU35_H2 0.83 2.02E−02 F 13 Table 45. “Correl. Set ID”—correlation set ID according to the correlated parameters Table above.

Example 10 Production of Tomato Transcriptom and High Throughput Correlation Analysis Using 44K Tomato Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis between NUE related phenotypes and gene expression, the present inventors utilized a Tomato oligonucleotide micro-array, produced by Agilent Technologies [Hypertext Transfer Protocol://World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?lPage=50879]. The array oligonucleotide represents about 44,000 Tomato genes and transcripts. In order to define correlations between the levels of RNA expression with NUE, ABST, yield components or vigor related parameters various plant characteristics of 18 different Tomato varieties were analyzed. Among them, 10 varieties encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [Hypertext Transfer Protocol://World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Correlation of Tomato Varieties Across Ecotypes Grown Under Low Nitrogen, Drought and Regular Growth Conditions

Experimental Procedures:

10 Tomato varieties were grown in 3 repetitive blocks, each containing 6 plants per plot were grown at net house. Briefly, the growing protocol was as follows:

1. Regular growth conditions: Tomato varieties were grown under normal conditions (4-6 Liters/m² of water per day and fertilized with NPK as recommended in protocols for commercial tomato production).

2. Low Nitrogen fertilization conditions: Tomato varieties were grown under normal conditions (4-6 Liters/m² per day and fertilized with NPK as recommended in protocols for commercial tomato production) until flower stage. At this time, Nitrogen fertilization was stopped.

3. Drought stress: Tomato variety was grown under normal conditions (4-6 Liters/m² per day) until flower stage. At this time, irrigation was reduced to 50% compared to normal conditions. Plants were phenotyped on a daily basis following the standard descriptor of tomato (Table 47). Harvest was conducted while 50% of the fruits were red (mature). Plants were separated to the vegetative part and fruits, of them, 2 nodes were analyzed for additional inflorescent parameters such as size, number of flowers, and inflorescent weight. Fresh weight of all vegetative material was measured. Fruits were separated to colors (red vs. green) and in accordance with the fruit size (small, medium and large). Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute). Data parameters collected are summarized in Table 47, hereinbelow.

Analyzed Sorghum tissues—Two tissues at different developmental stages [flower and leaf], representing different plant characteristics, were sampled and RNA was extracted as described above. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 46 below.

TABLE 46 Tomato transcriptom expression sets Expression Set Set ID Leaf grown under Normal Conditions A Leaf grown under 50% Irrigation B Flower grown under Normal Conditions C Flower grown under 50% Irrigation D Leaf grown under Low Nitrogen E Flower grown under Low Nitrogen F Table 46: Provided are the identification (ID) letters of each of the tomato expression sets.

The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 48, 49 and 50 below. Subsequent correlation analysis was conducted (Tables 51-52) with the correlation coefficient (R) and the p-values. Results were integrated to the database.

TABLE 47 Tomato correlated parameters (vectors) Correlation Correlation ID Fruit Yield/Plant Drought [gr.] 1 FW/Plant Drought [gr.] 2 average red fruit weight Drought [gr.] 3 RWC Drought [%] 4 Num of flowers (Drought) [number] 5 Weight flower clusters (Drought) [gr.] 6 Fruit yield/Plant (Normal) [gr.] 7 FW/Plant (Normal) [gr.] 8 average red fruit weight (Normal) [gr.] 9 SPAD (Normal) [SPAD unit] 10 RWC (Normal) [%] 11 SPAD 100% RWC (Normal) 12 No flowers (Normal) [number] 13 Weight Flower clusters (Normal) [gr.] 14 Fruit Yield/Plant (NUE) [gr.] 15 FW/Plant (NUE) [gr.] 16 average red fruit weight (NUE) [gr.] 17 SPAD NUE [SPAD unit] 18 RWC NUE [%] 19 SPAD loo % RWC (NUE) [SPAD unit] 20 No flowers (NUE) [number] 21 Weight clusters (flowers) (NUE) [gr.] 22 Table 47. Provided are the tomato correlated parameters.

Fruit Yield (grams)—At the end of the experiment [when 50% of the fruit were ripe (red)] all fruits from plots within blocks A-C were collected. The total fruits were counted and weighted. The average fruits weight was calculated by dividing the total fruit weight by the number of fruits.

Plant Fresh Weight (grams)—At the end of the experiment [when 50% of the fruit were ripe (red)] all plants from plots within blocks A-C were collected. Fresh weight was measured (grams).

Inflorescence Weight (grams)—At the end of the experiment [when 50% of the fruits were ripe (red)] two Inflorescence from plots within blocks A-C were collected. The Inflorescence weight (gr.) and number of flowers per inflorescence were counted.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at time of flowering. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Water use efficiency (WUE)—can be determined as the biomass produced per unit transpiration. To analyze WUE, leaf relative water content was measured in control and transgenic plants. Fresh weight (FW) was immediately recorded; then leaves were soaked for 8 hours in distilled water at room temperature in the dark, and the turgid weight (TW) was recorded. Total dry weight (DW) was recorded after drying the leaves at 60° C. to a constant weight. Relative water content (RWC) was calculated according to the following Formula I [(FW−DW/TW−DW)×100] as described above.

Plants that maintain high relative water content (RWC) compared to control lines were considered more tolerant to drought than those exhibiting reduced relative water content

Experimental Results

TABLE 48 Measured parameters in Tomato accessions under drought conditions Seed ID 1 2 3 4 5 6 612 0.467 2.62 0.00925 72.1 16.7 0.368 613 0.483 1.09 0.195 74.5 6.5 0.407 614 0.629 1.85 0.209 65.3 15.7 0.325 616 0.347 2.22 0.00467 72.2 20.3 0.288 617 2.04 2.63 0.102 66.1 11.7 0.551 618 0.25 2.71 0.00193 68.3 25.3 0.311 620 0.045 3.41 0.0346 78.1 29.7 0.445 621 0.453 2.11 0.00627 18.5 17.3 0.555 622 0.292 1.95 0.00527 73.2 14.7 0.304 623 1.02 1.76 0.00487 62.5 29.7 0.315 624 0.6 1.72 0.0052 67.2 15 0.308 625 0.494 1.92 0.012 75.8 10.3 0.311 626 0.272 2.21 0.00451 62.8 18.3 8.36 627 0.679 3.73 0.00632 70.7 12 0.288 628 0.14 0.754 0.303 55.8 20.3 0.342 629 0.529 1.76 0.138 75.2 12.7 0.441 630 0.554 0.626 0.0405 63.7 12.7 0.268 631 0.414 1.11 0.0885 62.3 11.3 0.426 Table 48: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under drought growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 49 Measured parameters in Tomato accessions under normal conditions Seed ID 7 8 9 10 11 12 13 14 612 0.826 1.53 0.0479 49.7 72.8 36.2 5.67 1.17 613 0.342 3.17 0.00799 37.2 76.5 28.4 19.3 0.342 614 0.494 3.02 0.00823 55.8 64.3 35.9 6.33 0.693 616 0.121 0.844 0.286 46.4 67.1 31.1 7.67 56.3 617 0.487 2.24 0.00503 48.2 54.8 26.4 9.67 0.44 618 0.454 1.98 0.0541 43.4 77.6 33.7 8.33 11.3 620 0.529 0.848 0.231 42.9 58.2 25 5 0.79 621 0.44 2.09 0.29 53.3 66.5 35.5 8.33 0.577 622 0.21 3.21 0.0061 58.5 64.7 37.9 10 0.73 623 0.31 2.75 0.0066 51.1 75.2 38.4 7 0.833 624 0.662 1.81 0.0577 40 66.2 26.5 9 0.86 625 0.189 3.77 0.007 47.6 63.2 30.1 8 0.5 626 0.852 1.89 0.0264 57.9 56.8 32.9 5.33 1.02 627 0.273 1.93 0.261 48.3 36 17.4 8 0.7 628 0.347 2.14 0.0289 43.6 77.6 33.8 7.67 0.377 629 0.327 1.65 0.00493 54.5 100 54.5 9 0.66 630 0.314 3.01 0.00343 41.6 63.2 26.3 10.7 0.7 631 0.291 2.29 0.00887 59.1 75.1 44.4 9 0.327 Table 49: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 50 Measured parameters in Tomato accessions under low nitrogen conditions Seed Id 15 16 17 18 19 20 21 22 612 0.406 4.04 0.0239 38.4 74.1 28.5 19 0.533 613 0.66 1.21 0.191 39.4 99.1 39 5.33 0.367 614 0.477 2.25 0.00647 47.5 69.5 33 9 0.307 616 0.458 2.54 0.0053 37 63.2 23.4 13 0.35 617 1.35 1.85 0.0963 44.6 77.4 34.5 10.7 0.473 618 0.354 3.06 0.0044 41.7 77.9 32.5 16.7 0.249 620 0.00889 3.13 0.00553 34.4 80.5 27.7 6 0.293 621 0.509 2.54 0.00747 50 67.4 33.7 16 0.467 622 0.436 1.84 0.0058 44.7 67.2 30 15 0.4 623 0.468 1.52 0.0127 53.7 66.1 35.5 6 0.303 624 1.59 1.91 0.0212 35.7 69.6 24.8 17 0.82 625 0.388 1.86 0.0052 58.8 69.3 40.8 13 0.4 626 0.323 2.47 0.00573 47.5 100 47.5 8.67 0.347 627 0.449 2.62 0.0475 45.2 57.7 26.1 9.33 0.428 628 0.143 1.08 0.357 39 90.8 35.4 12.7 0.353 629 0.396 1.17 0.0367 45 68 30.6 6.67 0.447 630 1.44 0.921 0.626 65.3 59.6 39 9.33 0.283 631 0.495 1.09 1.7 72.2 37.5 0.878 0.47 0.889 Table 50: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under low nitrogen growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 51 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal or drought stress conditions across Tomato accessions Gene P Exp. Correl. Gene P Exp. Correl. Name R value set Set ID Name R value set Set ID LNU20 0.85 1.78E−03 E 20 LNU288 0.87 1.10E−03 A 14 LNU245 0.95 7.41E−05 F 17 LNU288 0.83 2.98E−03 A 9 LNU245 0.84 2.23E−03 A 13 LNU288 0.83 3.30E−03 A 9 LNU245 0.73 1.66E−02 F 22 LNU288 0.80 5.50E−03 B 8 LNU246 0.71 2.25E−02 B 5 LNU288 0.77 9.78E−03 A 14 LNU29 1.00 5.21E−10 A 14 LNU288 0.72 1.90E−02 B 8 LNU229 0.74 1.50E−02 A 9 LNU289 0.82 6.93E−03 E 17 LNU229 0.72 1.80E−02 A 14 LNU289 0.75 1.22E−02 B 6 LNU200 0.86 1.29E−03 C 14 LNU289 0.75 1.24E−02 A 16 LNU289 0.70 3.52E−02 E 17 Table 51. “Correl. Set ID” - correlation set ID according to the correlated parameters Table above.

TABLE 52 Correlation between the expression level of selected LNU homologous genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal or drought stress conditions across Tomato accessions Correl. Correl. Gene P Exp. Set Gene P Exp. Set Name R value Set ID Name R value Set ID LNU128_H17 0.75 1.32E−02 A 10 LNU45_H302 0.80 5.89E−03 F 21 LNU128_H17 0.73 1.76E−02 A 10 LNU45_H302 0.76 1.08E−02 F 21 LNU46_H77 0.78 7.55E−03 F 18 LNU45_H302 0.76 1.14E−02 F 21 LNU74_H204 0.71 2.22E−02 D 2 LNU45_H301 0.76 1.14E−02 F 21 LNU45_H302 0.71 2.28E−02 D 2 LNU45_H300 0.82 3.93E−03 D 4 LNU74_H203 0.84 2.34E−03 F 21 LNU45_H300 0.72 1.87E−02 D 4 LNU74_H204 0.74 1.37E−02 F 21 LNU128_H17 0.74 1.40E−02 F 19 LNU45_H300 0.70 2.32E−02 A 12 Table 52. “Correl. Set ID” - correlation set ID according to the correlated parameters Table above.

Correlation of early vigor traits across collection of Tomato ecotypes under Low nitrogen, 300 mM NaCl, and normal growth conditions—Ten tomato hybrids were grown in 3 repetitive plots, each containing 17 plants, at a net house under semi-hydroponics conditions. Briefly, the growing protocol was as follows: Tomato seeds were sown in trays filled with a mix of vermiculite and peat in a 1:1 ratio. Following germination, the trays were transferred to the high salinity solution (300 mM NaCl in addition to the Full Hoagland solution), low nitrogen solution (the amount of total nitrogen was reduced in a 90% from the full Hoagland solution, final amount of 0.8 mM N) or at Normal growth solution (Full Hoagland containing 8 mM N solution, at 28±2° C.). Plants were grown at 28±2° C.

Full Hoagland solution consists of: KNO₃—0.808 grams/liter, MgSO₄—0.12 grams/liter, KH₂PO₄—0.172 grams/liter and 0.01% (volume/volume) of ‘Super coratin’ micro elements (Iron-EDDHA [ethylenediamine-N,N′-bis(2-hydroxyphenylacetic acid)]—40.5 grams/liter; Mn—20.2 grams/liter; Zn 10.1 grams/liter; Co 1.5 grams/liter; and Mo 1.1 grams/liter), solution's pH should be 6.5-6.8].

Analyzed Sorghum tissues—All 10 selected Tomato varieties were sample per each treatment. Three tissues [leaves, meristems and flowers] were sampled and RNA was extracted as described above. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 53 below.

TABLE 53 Tomato transcriptom experimental sets Expression Set Set ID Leaves at 300 mM NaCl A Leaves at Normal conditions B Leaves at Low Nitrogen conditions C Roots at 100 mM NaCl D Roots at Normal conditions E Roots at Low Nitrogen conditions F Table 53. Provided are the tomato transcriptom experimental sets.

Tomato vigor related parameters—following 5 weeks of growing, plant were harvested and analyzed for Leaf number, plant height, and Plant weight. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute). Data parameters collected are summarize in Table 54, hereinbelow.

TABLE 54 Tomato correlated parameters (vectors) Correlation Set Correlation ID Plant height NUE [cm] 1 SPAD NUE [SPAD unit] 2 leaf No NUE [number] 3 leaf No Normal [number] 4 Plant height Normal [cm] 5 SPAD Normal [SPAD unit] 6 Leaf No NaCl [number] 7 Plant height NaCl [cm] 8 Plant biomass_NaCl [gr] 9 Table 54. Provided are the tomato correlated parameters.

Experimental Results

10 different Tomato varieties were grown and characterized for 3 parameters as described above. The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 55 below. Subsequent correlation analysis was conducted (Tables 56 and 57). Follow, results were integrated to the database.

TABLE 55 Measured parameters in Tomato accessions under normal, salinity and low nitrogen conditions Seed ID 1 2 3 4 5 6 7 8 9 1139 36.8 34.6 5.56 6.56 45.3 34.3 3.56 5.6 0.36 2078 39.9 24.9 6.22 6.89 47.8 25.3 3.94 6.46 0.44 2958 34.4 28.6 7.22 7.33 40.8 28.1 5 8.47 0.26 5077 47 31.6 6.78 6.22 55.3 31.4 4 8.56 0.71 5080 46.4 29.7 5.56 6.33 56.2 30.2 3.56 8.87 0.46 5084 45.4 31.8 6.56 6.44 48.7 32.4 4.39 7.56 0.54 5085 47.7 30.3 5.11 5.89 55.8 32.6 3.17 8.64 0.66 5088 39.3 30.3 5.89 5.56 37.4 28.8 3.72 5.57 0.4 5089 41.8 31.3 5.56 6.11 49.6 30.9 4 5.82 0.52 5092 41 28.8 6.33 5.67 46.3 29 4.28 9.36 0.45 Table 55

TABLE 56 Correlation between the expression level of selected LNU genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal or salinity stress conditions across Tomato accessions Gene Name R P value Exp. set Correl. Set ID LNU245 0.81 1.41E−02 E 6 Table 56. “Correl. Set ID” - correlation set ID according to the correlated parameters Table above.

TABLE 57 Correlation between the expression level of selected LNU homologous genes of some embodiments of the invention in various tissues and the phenotypic performance under low nitrogen, normal or salinity stress conditions across Tomato accessions Correl. Correl. Gene P Exp. Set Gene P Exp. Set Name R value Set ID Name R value Set ID LNU128_H17 0.73 4.14E−02 B 4 LNU46_H78 0.88 4.04E−03 C 3 LNU128_H17 0.71 4.86E−02 B 4 LNU7_H146 0.77 2.68E−02 F 3 LNU128_H17 0.72 4.35E−02 E 4 LNU74_H204 0.71 4.70E−02 F 3 LNU74_H203 0.71 4.77E−02 C 3 LNU74_H205 0.75 1.20E−02 D 9 LNU46_H78 0.88 3.94E−03 C 3 LNU7_H146 0.74 1.38E−02 D 8 Table 57. “Correl. Set ID” - correlation set ID according to the correlated parameters Table above.

Example 11 Gene Cloning and Generation of Binary Vectors for Plant Expression

To validate their role in improving yield, selected genes were over-expressed in plants, as follows.

Cloning Strategy

Selected genes from those presented in Examples 1-10 hereinabove were cloned into binary vectors for the generation of transgenic plants. For cloning, the full-length open reading frames (ORFs) were identified. EST clusters and in some cases mRNA sequences were analyzed to identify the entire open reading frame by comparing the results of several translation algorithms to known proteins from other plant species.

In order to clone the full-length cDNAs, reverse transcription (RT) followed by polymerase chain reaction (PCR; RT-PCR) was performed on total RNA extracted from leaves, roots or other plant tissues, growing under normal/limiting or stress conditions. Total RNA extraction, production of cDNA and PCR amplification is performed using standard protocols described elsewhere (Sambrook J., E. F. Fritsch, and T. Maniatis. 1989. Molecular Cloning. A Laboratory Manual, 2nd Ed. Cold Spring Harbor Laboratory Press, New York) which are well known to those skilled in the art. PCR products are purified using PCR purification kit (Qiagen)

Usually, 2 sets of primers were prepared for the amplification of each gene, via nested PCR (if required). Both sets of primers were used for amplification on cDNA. In case no product was obtained, a nested PCR reaction was performed. Nested PCR was performed by amplification of the gene using external primers and then using the produced PCR product as a template for a second PCR reaction, where the internal set of primers are used. Alternatively, one or two of the internal primers are used for gene amplification, both in the first and the second PCR reactions (meaning only 2-3 primers were designed for a gene). To facilitate further cloning of the cDNAs, an 8-12 bp extension was added to the 5′ of each internal primer. The primer extension includes an endonuclease restriction site. The restriction sites were selected using two parameters: (a) the restriction site does not exist in the cDNA sequence; and (b) the restriction sites in the forward and reverse primers were designed such that the digested cDNA was inserted in the sense direction into the binary vector utilized for transformation.

PCR products were digested with the restriction endonucleases (New England BioLabs Inc) according to the sites designed in the primers. Each digested PCR product was inserted into a high copy vector pBlue-script KS plasmid vector [pBlue-script KS plasmid vector, Hypertext Transfer Protocol://World Wide Web (dot) stratagene (dot) com/manuals/212205 (dot) pdf), or into plasmids originated from this vector. In case of the high copy vector originated from pBlue-script KS plasmid vector (pGXN or pGXNa), the PCR product was inserted in the high copy plasmid upstream to the NOS terminator (SEQ ID NO:4683) originated from pBI 101.3 binary vector (GenBank Accession No. U12640, nucleotides 4356 to 4693) and downstream to the 35S promoter (SEQ ID NO:4685). The digested products and the linearized plasmid vector are ligated using T4 DNA ligase enzyme (Roche, Switzerland).

In some cases PCR products were cloned without digestion into pCR-Blunt II-TOPO vector (Invitrogen).

Sequencing of the inserted genes was performed, using the ABI 377 sequencer (Applied Biosystems). In some cases, after confirming the sequences of the cloned genes, the cloned cDNA accompanied/or not with the NOS terminator was introduced into a modified pGI binary vector containing the At6669 promoter or the RootP promoter via digestion with appropriate restriction endonucleases. In any case the insert was followed by single copy of the NOS terminator (SEQ ID NO:5683).

Several DNA sequences of the selected genes are synthesized by GeneArt [Hypertext Transfer Protocol://World Wide Web (dot) geneart (dot) com/]. Synthetic DNA was designed in silico. Suitable restriction enzymes sites are added to the cloned sequences at the 5′ end and at the 3′ end to enable later cloning into the desired binary vector.

The pPI plasmid vector was constructed by inserting a synthetic poly-(A) signal sequence, originating from pGL3 basic plasmid vector (Promega, GenBank Accession No. U47295; nucleotides 4658-4811) into the HindIII restriction site of the binary vector pBI101.3 (Clontech, GenBank Accession No. U12640). pGI (FIG. 1) was similar to pPI, but the original gene in the backbone was GUS-Intron and not GUS.

The modified pGI vector (pQFN or pQNa_RP) was a modified version of the pGI vector in which the cassette was inverted between the left and right borders so the gene and its corresponding promoter are close to the right border and the NPTII gene was close to the left border.

At6669, the new Arabidopsis thaliana promoter sequence (SEQ ID NO:4687) or the Root P promoter sequence (SEQ ID NO:4688) was inserted in the modified pGI binary vector, upstream to the cloned genes, followed by DNA ligation and binary plasmid extraction from positive E. coli colonies, as described above. Colonies were analyzed by PCR using the primers covering the insert which were designed to span the introduced promoter and gene. Positive plasmids were identified, isolated and sequenced.

In case genomic DNA was cloned, the genes were amplified by direct PCR on genomic DNA extracted from leaf tissue using the DNAeasy kit (Qiagen Cat. No. 69104).

Table 58 below provides primers used for cloning of selected genes.

TABLE 58 The PCR primers used for cloning the genes of some embodiments of the invention into high copy vectors Restriction Enzymes Gene used for Name cloning Primers used for amplification LNU1 BamHI, KpnI LNU1_EF_BamHI (SEQ IN NO: 4689) (6669) AAAGGATCCAAATCTCAGCTTCACCATTCG LNU1_ER2_KpnI (SEQ IN NO: 4690) TTTGGTACCTTTCTTCGAGTCTGGTCTCATTATC LNU1 BamHI, KpnI LNU1_EF_BamHI (SEQ IN NO: 4689) (Root_P_F) AAAGGATCCAAATCTCAGCTTCACCATTCG LNU1_ER2_KpnI (SEQ IN NO: 4690) TTTGGTACCTTTCTTCGAGTCTGGTCTCATTATC LNU10 LNU10_NF_XhoI (SEQ IN NO: 4691) AAACTCGAGCATTAAATTCGATCGAGGCTTTC LNU10_EF_XhoI (SEQ IN NO: 4692) AAACTCGAGCAACTCGGTTGCATTAAATTCG LNU10_NR_EcoRV (SEQ IN NO: 4693) AAAGATATCAAATACAGCTTGATGGTCGGTG LNU10_ER_EcoRV (SEQ IN NO: 4694) AAAGATATCTGATATGGACATGTTTGCAAGG LNU100 BamHI, XhoI LNU100_EF_BamHI (SEQ IN NO: 4695) AAAGGATCCTAAAGCACTTCACCTTTGCTCC LNU100_ER_XhoI (SEQ IN NO: 4696) AAACTCGAGATACAAATATAACAAGCCAATCATGC LNU101 BamHI, XhoI LNU101_NF_BamHI (SEQ IN NO: 4697) AAAGGATCCTATATGTTACACGATGCCGTCC LNU101_NF_BamHI (SEQ IN NO: 4697) AAAGGATCCTATATGTTACACGATGCCGTCC LNU101_NR_XhoI (SEQ IN NO: 4698) AAACTCGAGCGACTCAAATTCATCTTAACAAGC LNU101_NR_XhoI (SEQ IN NO: 4698) AAACTCGAGCGACTCAAATTCATCTTAACAAGC LNU104 SalI, XbaI LNU104_ER_XbaI (SEQ IN NO: 4699) AAATCTAGAAAGCAAATTTCGTTTGCAACTC LYD104_EF_BamHI (SEQ IN NO: 4700) AAAGGATCCTCCCAATAAACCCTAATTCCTTG LNU104_EF_SalI (SEQ IN NO: 4701) AAAGTCGACTCCATTGGCCGTAGTAGCAG LNU105 BamHI, XhoI LNU105_EF_BamHI (SEQ IN NO: 4702) AAAGGATCCCTTCTTCCAGCTCCGGTTC LNU105_ER_XhoI (SEQ IN NO: 4703) AAACTCGAGACTCGTCATCTATGCACTCGAC LNU106 SalI, XbaI LNU106_NF_SalI (SEQ IN NO: 4704) AAAGTCGACACGTCTTGGTTTGTCGGTTAAG LNU106_EF_SalI (SEQ IN NO: 4705) AAAGTCGACGTCTCTTCCTCTCCACAAGCAC LNU106_NR_XbaI (SEQ IN NO: 4706) AAATCTAGATACCAGCGATTCATATTGGAGG LNU106_ER_XbaI (SEQ IN NO: 4707) AAATCTAGACGATCTCATAAACGGATTCGAG LNU107 BamHI, XhoI LNU107_NF_BamHI (SEQ IN NO: 4708) AAAGGATCCCCATTTCCATATTCCGTCTGTC LNU107_EF_BamHI (SEQ IN NO: 4709) AAAGGATCCCTTCTTCTGCGAATTTCCTCTG LNU107_R_XhoI (SEQ IN NO: 4710) AAACTCGAGCTACAAGCAGATCAACTCAGGGAG LNU107_R_XhoI (SEQ IN NO: 4710) AAACTCGAGCTACAAGCAGATCAACTCAGGGAG LNU109 XhoI, EcoRV LNU109_EF_XhoI (SEQ IN NO: 4711) AAACTCGAGAGCTCACACCGATCCAGTAATC LNU109_ER_EcoRV (SEQ IN NO: 4712) AAAGATATCCTTTATGGGAGAGGACATGCAC LNU110 BamHI, XhoI LYD110_EF_BamHI (SEQ IN NO: 4713) AAAGGATCCTAACCTCATAGTGTCGACATGG LYD110_ER_KpnI (SEQ IN NO: 4714) AAAGGTACCTTCACCAACTTATACGAACCAC LNU113 BamHI, XhoI LNU113_EF_BamHI (SEQ IN NO: 4715) AAAGGATCCGAGCAAGATCAATCCCTCTGC LNU113_ER_XhoI (SEQ IN NO: 4716) AAACTCGAGGAAGAAAGCCATCACAAGCATC LNU114 SalI, XbaI LNU114_EF_SalI (SEQ IN NO: 4717) AAAGTCGACTGGTAGTGAACCGTGAACACAC LNU114_ER_XbaI (SEQ IN NO: 4718) AAATCTAGAACAGGAGCTCAGAAGCTTCAAC LNU115 SmaI, KpnI LNU115_EF2_SmaI (SEQ IN NO: 4719) AAACCCGGGGTGTCCCTGTACCAGATCCAC LNU115_ER2_KpnI (SEQ IN NO: 4720) AAAGGTACCCTCCAAAATTATCATTAACACCG LNU116 BamHI, KpnI LNU116_NF_BamHI (SEQ IN NO: 4721) AAAGGATCCTTGATCCATTCATCTTTGTTGG LNU116_EF_BamHI (SEQ IN NO: 4722) AAAGGATCCGCTTGTGTTTCTCGAAATTGTG LNU116_R_KpnI (SEQ IN NO: 4723) AAAGGTACCAAGAATGGCCTAAGCTACCGAC LNU116_R_KpnI (SEQ IN NO: 4723) AAAGGTACCAAGAATGGCCTAAGCTACCGAC LNU117 BamHI, XhoI LNU117_NF_BamHI (SEQ IN NO: 4724) AAAGGATCCGCATGAGCATGACTCCTCAC LNU117_EF_BamHI (SEQ IN NO: 4725) AAAGGATCCGAGACCAGACGCAGAAGATGTC LNU117_NR_XhoI (SEQ IN NO: 4726) AAACTCGAGACTATTTGCCGTGCATAACGAC LNU117_ER_XhoI (SEQ IN NO: 4727) AAACTCGAGACAAACAACCGCGTAAGAAGAG LNU118 BamHI, XhoI LNU118_NF_BamHI (SEQ IN NO: 4728) (6669) AAAGGATCCCTAATTCAGCTAAGGATTTGGAGG LNU118_NR_XhoI (SEQ IN NO: 4729) AAACTCGAGCGCTGACTCGATCGTTGAC LNU118 BamHI, XhoI LNU118_NF_BamHI (SEQ IN NO: 4728) (Root_P_F) AAAGGATCCCTAATTCAGCTAAGGATTTGGAGG LNU118_NR_XhoI (SEQ IN NO: 4729) AAACTCGAGCGCTGACTCGATCGTTGAC LNU119 BamHI, XhoI LNU119_NF_BamHI (SEQ IN NO: 4730) AAAGGATCCTTGCTACCCACCACGAGAG LNU119_EF_BamHI (SEQ IN NO: 4731) AAAGGATCCATATACGAGCCTTTGCTACCCAC LNU119_NR_XhoI (SEQ IN NO: 4732) AAACTCGAGTGCCAACTGTCTGAGATCTTTC LNU119_ER_XhoI (SEQ IN NO: 4733) AAACTCGAGATTGTGTCTTTGAGCTGCCAAC LNU12 BamHI, KpnI LNU12_NF_BamHI (SEQ IN NO: 4734) AAAGGATCCCTAGCGAACTACGTGTGCTCC LNU12_EF_BamHI (SEQ IN NO: 4735) AAAGGATCCGCTCTTCACACGGCTAACG LNU12_NR_KpnI (SEQ IN NO: 4736) AAAGGTACCGTTTCCACGCAAGGAAGAATC LNU12_ER_KpnI (SEQ IN NO: 4737) AAAGGTACCGTTCGATTCGGCTCTGTTTC LNU120 SalI, XbaI LNU120_NF_SalI (SEQ IN NO: 4738) AAAGTCGACGTCATCACACATTGGCAGC LNU120_EF_SalI (SEQ IN NO: 4739) AAAGTCGACATCAGTCATCACACATTGGCAG LNU120_NR_XbaI (SEQ IN NO: 4740) AAATCTAGAACATGGTTGATCTTGAGCTGTG LNU120_ER_XbaI (SEQ IN NO: 4741) AAATCTAGACGACATGGTTGATCTTGAGC LNU121 XhoI, StuI LNU121_F_XhoI (SEQ IN NO: 4742) AAACTCGAGAAAAACGCGCAATCCCG LNU121_ER_StuI (SEQ IN NO: 4743) TTTAGGCCTGGGTTTGGTCATGTACAGTCAC LNU122 LNU122_NF_BamHI (SEQ IN NO: 4744) AAAGGATCCAACGAATAGCCAAGCTCAGTTC LNU122_NR_KpnI (SEQ IN NO: 4745) AAAGGTACCATTTGATTATTTGTGGTGTACAATGC LNU123 BamHI, XhoI LNU123_F_BamHI (SEQ IN NO: 4746) AAAGGATCCGATCCGAAAGGATCTCCACC LNU123_F_BamHI (SEQ IN NO: 4746) AAAGGATCCGATCCGAAAGGATCTCCACC LNU123_NR_XhoI (SEQ IN NO: 4747) AAACTCGAGATGCTTCCTCATTGTTTGATCC LNU123_ER_XhoI (SEQ IN NO: 4748) AAACTCGAGATACCAATTCTAACCGTGGTCG LNU124 BamHI, KpnI LNU124_NF_BamHI (SEQ IN NO: 4749) AAAGGATCCAATTAATTCGAAAGAGCGGTCAC LNU124_EF_BamHI (SEQ IN NO: 4750) AAAGGATCCATTCACTACATGCACAAGCACG LNU124_NR_KpnI (SEQ IN NO: 4751) AAAGGTACCCTAGATCCAATGGAGAGACAGAGC LNU124_ER_KpnI (SEQ IN NO: 4752) AAAGGTACCAAAGTCTCTGGAGTTGATGAAATTG LNU125 SalI, SacI LNU125_F2_Sal (SEQ IN NO: 4753) TTTGTCGACTGACTTTAAAAATTTGAACGTGAA LNU125_R2_Sac (SEQ IN NO: 4754) TTTGAGCTCGTGGAAGGTTACACTGTTGTATTTC LNU126 BamHI, XhoI LNU126_F_BamHI (SEQ IN NO: 4755) AATGGATCCCTATCACAAAGCCTAGAGTAAAATCG LNU126_F_BamHI (SEQ IN NO: 4755) AATGGATCCCTATCACAAAGCCTAGAGTAAAATCG LNU126_NR_XhoI (SEQ IN NO: 4756) AAACTCGAGGCAACACAAGGAACTGTACTATCTC LNU126_ER_XhoI (SEQ IN NO: 4757) TTTCTCGAGTCAGCGGTTACTTTGTCGTTAC LNU128 BamHI, XhoI LNU128_F_BamHI (SEQ IN NO: 4758) AAAGGATCCAGGCGAAGAAGAGAGAGGAATG LNU128_F_BamHI (SEQ IN NO: 4758) AAAGGATCCAGGCGAAGAAGAGAGAGGAATG LNU128_NR_XhoI (SEQ IN NO: 4759) AAACTCGAGCTATAAGGCACAGGTCCAATTCAAG LNU128_ER_XhoI (SEQ IN NO: 4760) AAACTCGAGTGATTCGATCATGTATTTCACATTG LNU129 BamHI, XhoI LNU129_NF_BamHI (SEQ IN NO: 4761) AAAGGATCCGTTTGTCTCGCATGAGGATTTG LNU129_NF_BamHI (SEQ IN NO: 4761) AAAGGATCCGTTTGTCTCGCATGAGGATTTG LNU129_NR_XhoI (SEQ IN NO: 4762) AAACTCGAGTGAAATTTCTCTGTTGGATTGATG LNU129_NR_XhoI (SEQ IN NO: 4762) AAACTCGAGTGAAATTTCTCTGTTGGATTGATG LNU130 SalI, XbaI LNU130_F_SalI (SEQ IN NO: 4763) AAAGTCGACCTGAAAGACGAAGAAGAGAAACG LNU130_F_SalI (SEQ IN NO: 4763) AAAGTCGACCTGAAAGACGAAGAAGAGAAACG LNU130_NR_XbaI (SEQ IN NO: 4764) AAATCTAGAATGAACAACGGTTTCAATGGAC LNU130_ER_XbaI (SEQ IN NO: 4765) AAATCTAGAATCGGTGTAAGTGAACACGATG LNU131 BamHI, XhoI LNU131_EF_BamHI (SEQ IN NO: 4766) AAAGGATCCCTTCTTCTTCTTCGATTTAGCACAG LNU131_ER_XhoI (SEQ IN NO: 4767) AAACTCGAGCATTGTTGGCTGTATATTTCATCAC LNU132 SalI, XbaI LNU132_F_SalI (SEQ IN NO: 4768) AAAGTCGACTCTTTCTGCAGAGATTATGGAGG LNU132_ER_XbaI (SEQ IN NO: 4769) AAATCTAGAAATCGCAGAGAAGCAAACAGAC LNU133 SalI, XbaI LNU133_EF_SalI (SEQ IN NO: 4770) AAAGTCGACAAATTTCCAGAGAAGTCGTTCATC LNU133_ER_XbaI (SEQ IN NO: 4771) AAATCTAGAATTACAGCATCAAACAGCCAGC LNU134 BamHI, XhoI LNU134_NF_BamHI (SEQ IN NO: 4772) AAAGGATCCAGGTTTCTTTCGATTCGTTGAG LNU134_EF_BamHI (SEQ IN NO: 4773) AAAGGATCCGTTATTCTCAATCCTTCCTTCATCC LNU134_NR_XhoI (SEQ IN NO: 4774) AAACTCGAGCTACCTGTACTTTGGGAATAAGCAGAG LNU134_ER_XhoI (SEQ IN NO: 4775) AAACTCGAGGAGTTCTTTCACATCATGGACG LNU135 BamHI, XhoI LNU135_EF_BamHI (SEQ IN NO: 4776) AAAGGATCCAGCCGTTTCTTTCCGATTC LNU135_ER_XhoI (SEQ IN NO: 4777) AAACTCGAGACGAGAAATATGATCACTGGAAATC LNU136 BamHI, KpnI LNU136_EF_BamHI (SEQ IN NO:4778) AAAGGATCCTCGGAGACTGAATGATATTGTTTC LNU136_ER_KpnI (SEQ IN NO: 4779) AAAGGTACCTTCAAAGAATGTGTCTTGTGTGTG LNU138 EcoRV, SalI LNU138_EF_SalI (SEQ IN NO: 4780) AAAGTCGACATAAAGATCGTCCACAAGGAGG LNU138_ER_EcoRV (SEQ IN NO: 4781) AAAGATATCCAATCAGCATACAAAGGCACAC LNU14 EcoRV, XhoI LNU14_EF_XhoI (SEQ IN NO: 4782) AAACTCGAGTTCTTAGGGACCATTCCTCCTC LNU14_R_EcoRV (SEQ IN NO: 4783) AAAGATATCCTATGGTTTCATCAAATAAGACACACA LNU140 SalI, XbaI LNU140_NF_SalI (SEQ IN NO: 4784) AAAGTCGACGCTGTTTCTTCCCGATCTTTG LNU140_EF_SalI (SEQ IN NO: 4785) AAAGTCGACGTTAACCTCTCCTCGTTCTCGTC LNU140_NR_XbaI (SEQ IN NO: 4786) AAATCTAGACTATCGAGAGGATTTACAATGGCAG LNU140_ER_XbaI (SEQ IN NO: 4787) AAATCTAGACGAATCATGAGACAAACAAACC LNU141 BamHI, XhoI LNU141_NF_BamHI (SEQ IN NO: 4788) AAAGGATCCCGTCTCACTTCATCCCATCC LNU141_EF_BamHI (SEQ IN NO: 4789) AAAGGATCCCTTCCGACCTCACGAAAGC LNU141_NR_XhoI (SEQ IN NO: 4790) AAACTCGAGACGGCTTAAGATTTGTACAGCAC LNU141_ER_XhoI (SEQ IN NO: 4791) AAACTCGAGCACCATCTATGCACGTCAACTG LNU143 BamHI, XhoI LNU143_EF_BamHI (SEQ IN NO: 4792) AATGGATCCCAAGCCTACGGTGTTCATGAC LNU143_ER_XhoI (SEQ IN NO: 4793) AAACTCGAGCATCTATAGGGAACACGAATGAGC LNU147 BamHI, XhoI LNU147_EF_BamHI (SEQ IN NO: 4794) AAAGGATCCCTCTTCTTGAACATGACAAAGACC LNU147_ER_XhoI (SEQ IN NO: 4795) AAACTCGAGAGGATTCACGCCATACAGTTTAG LNU148 BamHI, XhoI LNU148_F_BamHI (SEQ IN NO: 4796) TTTGGATCCGTCTATTGCATTGAGTTGAAATCAC LNU148_F_BamHI (SEQ IN NO: 4796) TTTGGATCCGTCTATTGCATTGAGTTGAAATCAC LNU148_NR_XhoI (SEQ IN NO: 4797) AATCTCGAGTCAATCAAATTGTGTATTCAAATGTATA TAC LNU148_ER_XhoI (SEQ IN NO: 4798) TATCTCGAGTCCCAAAATTCAAGCTAACAGTC LNU149 BamHI, XhoI LNU149_NF_BamHI (SEQ IN NO: 4799) AAAGGATCCATTCAGAATTGGAGAGGGAAGG LNU149_EF_BamHI (SEQ IN NO: 4800) AAAGGATCCCTAGCTCAGGCCATTGAAGAAC LNU149_NR_XhoI (SEQ IN NO: 4801) AAACTCGAGCCGGGTTTACTCAGTATGAAGC LNU149_ER_XhoI (SEQ IN NO: 4802) AAACTCGAGGAGCTTACACGAACGTTTCTCC LNU15 SalI, XbaI LNU15_NF_SalI (SEQ IN NO: 4803) AAAGTCGACCTTCTCTCCGCAACACTGAAAC LNU15_EF_SalI (SEQ IN NO: 4804) AAAGTCGACACCAAACTTTGCCTTTCTCTCTC LNU15_NR_XbaI (SEQ IN NO: 4805) AAATCTAGAGGTTCCTTATTATTTCACACCCAAG LNU15_ER_XbaI (SEQ IN NO: 4806) AAATCTAGAAGAACATCAAATCTAGTCGCAGTG LNU150 SalI, XbaI LNU150_EF_SalI (SEQ IN NO: 4807) AAAGTCGACCACCGCTTTGTGGAAACAG LNU150_ER_XbaI (SEQ IN NO: 4808) AAATCTAGAGGCAGTTGCTTCCATTATTGC LNU153 BamHI, XhoI LNU153_EF_BamHI (SEQ IN NO: 4809) AAAGGATCCTGTCCACTTTGGTTCCTTCTTC LNU153_ER_XhoI (SEQ IN NO: 4810) AAACTCGAGTGCTCTACAATCATCACCATCC LNU154 XhoI, EcoRV LNU154_EF_XhoI (SEQ IN NO: 4811) AAACTCGAGCAAAGAAGAAACTAGTTGTAGGCAGC LNU154_ER_EcoRV (SEQ IN NO: 4812) AAAGATATCTGGTAATGATACAAGCTCAAGCAAC LNU155 SalI, XbaI LNU155_EF_SalI (SEQ IN NO: 4813) AAAGTCGACTTCTTTACCCATTATTGCACTCAC LNU155_ER_XbaI (SEQ IN NO: 4814) AAATCTAGACAGTTTCCACAAATTCTCAATTACG LNU157 SalI, XbaI LNU157_EF_SalI (SEQ IN NO: 4815) AAAGTCGACCAAAGTTCACACACAGAAGAATCAG LNU157_R_XbaI (SEQ IN NO: 4816) ATTTCTAGATCTTTCAATTACTTCAATTAGCCTCC LNU158 BamHI, XhoI LNU158_NF_BamHI (SEQ IN NO: 4817) TTTGGATCCGAAAGTTCCTCACAATCATTTGTC LNU158_EF_BamHI (SEQ IN NO: 4818) TTTGGATCCGCACCCTTTGGTAGATTCTCG LNU158_NR_XhoI (SEQ IN NO: 4819) ATTCTCGAGTCAAAGATTGAAGGTATCATATGCTGTT CA LNU158_ER_XhoI (SEQ IN NO: 4820) TTTCTCGAGTGGTTTGTGGGTAATCTTCTGC LNU161 SalI, XbaI LNU161_NF_SalI (SEQ IN NO: 4821) AAAGTCGACACTTTCTCTCTTCGGGTTCTCG LNU161_NF_SalI (SEQ IN NO: 4821) AAAGTCGACACTTTCTCTCTTCGGGTTCTCG LNU161_NR_XbaI (SEQ IN NO: 4822) AAATCTAGAATCGCTTATTTCCGACCACAC LNU161_NR_XbaI (SEQ IN NO: 4822) AAATCTAGAATCGCTTATTTCCGACCACAC LNU168 XhoI, XbaI LNU168_EF_XhoI (SEQ IN NO: 4823) AAACTCGAGCTTCCCTTCCATACTTGCTTCC LNU168_ER_SacI (SEQ IN NO: 4824) AAAGAGCTCTGTCACTCAAAGGTAGCTGAGG LNU17 BamHI, KpnI LNU17_EF_BamHI (SEQ IN NO: 4825) AAAGGATCCTGCCATAAGCTTCCATCCTATC LNU17_ER_KpnI (SEQ IN NO: 4826) AAAGGTACCTGTGCTTCCTAAGCTTTCAACTC LNU170 SalI, SacI LNU170_NF_SalI (SEQ IN NO: 4827) TTAGTCGACATGTAATGGCTACTTCTTCCTCTTCTTG LNU170_EF_SalI (SEQ IN NO: 4828) TTAGTCGACATGTTCTTCACTGTAATGTAATGGCTAC LNU170_NR_SacI (SEQ IN NO: 4829) ATAGAGCTCCAATGCATGAATTCCTCGTG LNU170_ER_SacI (SEQ IN NO: 4830) TAAGAGCTCCTGATTACGTTAGGTAGGTGTGTGTATC LNU171 SalI, XbaI LNU171_NF_SalI (SEQ IN NO: 4831) AAAGTCGACCTAGCAGAGGCAGAGCCTACAG LNU171_F2_Sal (SEQ IN NO: 4832) AATGTCGACCGATCAACTAGGCAACTAGCA LNU171_NR_XbaI (SEQ IN NO: 4833) AAATCTAGACTACTAAGCATGAACACCTGGTGAG LNU171_R2_Xba (SEQ IN NO: 4834) AAATCTAGAGAGAAATCTGTTCCTGGACACA LNU172 XhoI, EcoRV LNU172_EF_XhoI (SEQ IN NO: 4835) AAACTCGAGCGAGCACTTCTCTAGCTCATGC LNU172_ER_EcoRV (SEQ IN NO: 4836) AAAGATATCGAACCCAATCCGAATTAATTGAC LNU173 SalI, XbaI LNU173_NF_SalI (SEQ IN NO: 4837) AAAGTCGACACATCGTACGTCCGTTCCAG LNU173_NF_SalI (SEQ IN NO: 4837) AAAGTCGACACATCGTACGTCCGTTCCAG LNU173_NR_XbaI (SEQ IN NO: 4838) AAATCTAGAAACGGAACATTTGAATGACTGC LNU173_NR_XbaI (SEQ IN NO: 4838) AAATCTAGAAACGGAACATTTGAATGACTGC LNU175 BamHI, XhoI LNU175_EF_BamHI (SEQ IN NO: 4839) AAAGGATCCTCTCTCATCTGCCTACGGTTG LNU175_ER_XhoI (SEQ IN NO: 4840) AAACTCGAGAATCATGCCTCTTGTCTTGGTG LNU176 SalI, XbaI LNU176_NF_SalI (SEQ IN NO: 4841) AAAGTCGACCTCTCTCAAGGTCTCACCAACC LNU176_NR_XbaI (SEQ IN NO: 4842) AAATCTAGATGCATTACACACAGTAACATCATCAG LNU177 SalI, XbaI LNU177_NF_SalI (SEQ IN NO: 4843) AAAGTCGACGATCATCATCAGACAATGGCAG LNU177_EF_SalI (SEQ IN NO: 4844) AAAGTCGACAATTTCCATTGGTCCTCCTCTC LNU177_R_XbaI (SEQ IN NO: 4845) AAATCTAGAACATTTGAATCCCAAAGATGATTT LNU177_R_XbaI (SEQ IN NO: 4845) AAATCTAGAACATTTGAATCCCAAAGATGATTT LNU178 BamHI, XhoI LNU178_EF_BamHI (SEQ IN NO: 4846) AAAGGATCCTCTCTCTTGTTCTGAATTCGTGG LNU178_ER_XhoI (SEQ IN NO: 4847) AAACTCGAGGACAGAGAGAAGCTATGACCAACTG LNU179 BamHI, XhoI LNU179_F_BamHI (SEQ IN NO: 4848) AAAGGATCCGAGATAGAGAGAGAGATAATGGGCA LNU179_ER_XhoI (SEQ IN NO: 4849) AAACTCGAGTGCACACTTAAATCAACAAGCA LNU180 BamHI, XhoI LNU180_NF_BamHI (SEQ IN NO: 4850) AAAGGATCCGTTCTATGTTCCTGAAATGGGATT LNU180_EF_BamHI (SEQ IN NO: 4851) AAAGGATCCGAAACAAGCTCCATATCAATAATCAA LNU180_NR_XhoI (SEQ IN NO: 4852) AAACTCGAGGAACGGAAGAAATAACCAACAAA LNU180_ER_XhoI (SEQ IN NO: 4853) AAACTCGAGATGGTTTGAAGAACGGAAGAAA LNU181 BamHI, KpnI LNU181_NF_BamHI (SEQ IN NO: 4854) AAAGGATCCGATTTCTTCGTCAGTTGCGTTT LNU181_EF_BamHI (SEQ IN NO: 4855) AAAGGATCCCGGTCCTAAACCCTACTCAACA LNU181_NR_KpnI (SEQ IN NO: 4856) AAAGGTACCAAATCTCATAGCTTATCATGCTCAAA LNU181_ER_KpnI (SEQ IN NO: 4857) AAAGGTACCTTCAGCCGTATCATCGTCTATTT LNU182 BamHI, XhoI LNU182_NF_BamHI (SEQ IN NO: 4858) AAAGGATCCCGTTGTGTTCCAACTCTCATTC LNU182_EF_BamHI (SEQ IN NO: 4859) AAAGGATCCGATTTGCGAGTCGTTGTGTTC LNU182_NR_XhoI (SEQ IN NO: 4860) AAACTCGAGGATCTTGAGGAACATGGAGACG LNU182_ER_XhoI (SEQ IN NO: 4861) AAACTCGAGGTGACTTTGGTTCCGATTTGAG LNU183 BamHI, XhoI LNU183_F_BamHI (SEQ IN NO: 4862) AACGGATCCAAGCTCTAGACTTTGTCTCTTTGTCC LNU183_F_BamHI (SEQ IN NO: 4862) AACGGATCCAAGCTCTAGACTTTGTCTCTTTGTCC LNU183_NR_XhoI (SEQ IN NO: 4863) AATCTCGAGTCACACCAATACAACCATAAATAACAC LNU183_ER_XhoI (SEQ IN NO: 4864) AATCTCGAGACTGCTGAAGTCAAAGCTAATTAGAAC LNU184 BamHI, XhoI LNU184_NF_BamHI (SEQ IN NO: 4865) AAAGGATCCCCTACCTAATCCACACCGATTC LNU184_EF_BamHI (SEQ IN NO: 4866) AAAGGATCCGAAGTGGAGAGAAGTGACCACC LNU184_NR_XhoI (SEQ IN NO: 4867) AAACTCGAGCAGCATGAGAAGAGATTTCGAG LNU184_ER_XhoI (SEQ IN NO: 4868) AAACTCGAGCAGCAACAACAAGAGATTTGTCC LNU185 BamHI, XhoI LNU185_NF_BamHI (SEQ IN NO: 4869) AAAGGATCCACAAACGGTGTGTAAGTGAAGAAG LNU185_EF_BamHI (SEQ IN NO: 4870) AAAGGATCCTCAGTCTGAAGACAAACGGTG LNU185_NR_XhoI (SEQ IN NO: 4871) AAACTCGAGCCGCAGAGGCTTTGTTAAATTC LNU185_ER_XhoI (SEQ IN NO: 4872) AAACTCGAGAAGGACATCATCAAAGCAGTACG LNU186 BamHI, XhoI LNU186_EF_BamHI (SEQ IN NO: 4873) AAAGGATCCATTGAGAGTCGCCACAGCTATC LNU186_ER_XhoI (SEQ IN NO: 4874) AAACTCGAGTGGCTTGATAAAGATTTGTGATTTC LNU187 XhoI, EcoRV LNU187_NF_XhoI (SEQ IN NO: 4875) AAACTCGAGCTCCTTCTTTACTTCGCTCACC LNU187_EF_XhoI (SEQ IN NO: 4876) AATCTCGAGTTTATCTCCTTCTTTACTTCGCTCAC LNU187_NR_EcoRV (SEQ IN NO: 4877) AATGATATCTTTGAAGCTAAACGATTTGACTAATTC LNU187_ER_EcoRV (SEQ IN NO: 4878) AATGATATCCCGCCACATTCATTTCAG LNU188 BamHI, XhoI LNU188_NF_BamHI (SEQ IN NO: 4879) AAAGGATCCAGAGCTTGCTCGGAGAGAGTG LNU188_EF_BamHI (SEQ IN NO: 4880) AAAGGATCCACAGAGAGATGCAGACCTGACC LNU188_NR_XhoI (SEQ IN NO: 4881) AAACTCGAGCCCTGATTCTCCTGTTGAGAAC LNU188_ER_XhoI (SEQ IN NO: 4882) AAACTCGAGTAAAGCTCGATTTCCCTGATTC LNU189 BamHI, XhoI LNU189_EF_BamHI (SEQ IN NO: 4883) AAAGGATCCAACAGACTGAATCATCAACGGAC LNU189_ER_XhoI (SEQ IN NO: 4884) AAACTCGAGCACGAGATGATAAGGGTTGGTC LNU19 XhoI, SacI LNU19_NF_XhoI (SEQ IN NO: 4885) AAACTCGAGGCAGCTCGTGTGTGATTGAG LNU19_NF_XhoI (SEQ IN NO: 4885) AAACTCGAGGCAGCTCGTGTGTGATTGAG LNU19_NR_SacI (SEQ IN NO: 4886) AAAGAGCTCTCGTTTCCTACAAATGCAACAG LNU19_NR_SacI (SEQ IN NO: 4886) AAAGAGCTCTCGTTTCCTACAAATGCAACAG LNU196 BamHI, KpnI LNU196_NF_BamHI (SEQ IN NO: 4887) AAAGGATCCGATCAATCCTTCTGCGTGTTC LNU196_EF_BamHI (SEQ IN NO: 4888) AAAGGATCCCCATATCACATCTCTGATCAATCC LNU196_NR_KpnI (SEQ IN NO: 4889) AAAGGTACCTACTGTGATCATAAGCTACGTGGAC LNU196_ER_KpnI (SEQ IN NO: 4890) AAAGGTACCGCACAACATGTGGTCAAATTATTC LNU2 BamHI, KpnI LNU2_NF_BamHI (SEQ IN NO: 4891) AAAGGATCCCTCCTCTTCCGCTCGAATTTAC LNU2_EF_BamHI (SEQ IN NO: 4892) AAAGGATCCACAACACCACAGCGCTCATAC LNU2_NR_KpnI (SEQ IN NO: 4893) AAAGGTACCAATCCTACCCACAACTGTCTGG LNU2_ER_KpnI (SEQ IN NO: 4894) AAAGGTACCTGAATTCCTCGCAAGAGTTACC LNU20 SalI, XbaI LNU20_EF_SalI (SEQ IN NO: 4895) AAAGTCGACGAAGTGTTATTTGGAGGCAAGG LNU20_ER_XbaI (SEQ IN NO: 4896) AAATCTAGAACCATCAAATTTAGCCATGCAC LNU200 XhoI, SacI LNU200_NF_XhoI (SEQ IN NO: 4897) AAACTCGAGATTTGGTCATAGTGTCGACATGG LNU200_EF_XhoI (SEQ IN NO: 4898) AAACTCGAGTGTGCTCCAAACTTGAAAGAAAG LNU200_NR_SacI (SEQ IN NO: 4899) AAAGAGCTCGACACGCAAATAGGACACACTG LNU200_ER_SacI (SEQ IN NO: 4900) AAAGAGCTCTTGAGACACGCAAATAGGACAC LNU207 BamHI, XhoI LNU207_NF_BamHI (SEQ IN NO: 4901) AAAGGATCCCTTGGAGCTAGGAGACATCGTG LNU207_EF_BamHI (SEQ IN NO: 4902) AAAGGATCCTTATTTCCCTAAATCCTTGGAGC LNU207_NR_XhoI (SEQ IN NO: 4903) AAACTCGAGCTGACCACTTAACACTCTCACTCG LNU207_ER_XhoI (SEQ IN NO: 4904) AAACTCGAGAATCTCCCATACGACACTGACC LNU210 BamHI, KpnI LNU210_EF_BamHI (SEQ IN NO: 4905) AAAGGATCCCGATCGATTGGTTTAAATCCTG LNU210_ER_KpnI (SEQ IN NO: 4906) AAAGGTACCTTACAATCACGACCACCTTGTAAC LNU211 SalI, XbaI LNU211_NF_SalI (SEQ IN NO: 4907) AAAGTCGACAACCTCCTTCTCAAACCGTAGG LNU211_EF_SalI (SEQ IN NO: 4908) AAAGTCGACAAAGGCCTAAGCTCAAGCAATC LNU211_NR_XbaI (SEQ IN NO: 4909) AAATCTAGAGGAAACCCTAATTTCCTTCTCC LNU211_ER_XbaI (SEQ IN NO: 4910) AAATCTAGAAAAGTTAGTGCTATTCGCGCTC LNU212 SalI, XbaI LNU212_F_SalI (SEQ IN NO: 4911) TTTGTCGACCTACTCACATCATGGCTTTCTCC LNU212_ER_XbaI (SEQ IN NO: 4912) ATTTCTAGATTCACCGAATAATATATGCAAACG LNU213 BamHI, XhoI LNU213_EF_BamHI (SEQ IN NO: 4913) (6669) AAAGGATCCCAAATTAGGAGGAGCGAGAGC LNU213_ER_XhoI (SEQ IN NO: 4914) AAACTCGAGATGATCAGAAATTCTCAACCACG LNU213 BamHI, XhoI LNU213_EF_BamHI(SEQ IN NO: 4913) (Root_P_F) AAAGGATCCCAAATTAGGAGGAGCGAGAGC LNU213_ER_XhoI (SEQ IN NO: 4914) AAACTCGAGATGATCAGAAATTCTCAACCACG LNU214 BamHI, XhoI LNU214_F_BamHI (SEQ IN NO: 4915) AAAGGATCCACTTCAAAGTACAAATTCCATTTCG LNU214_F_BamHI (SEQ IN NO: 4915) AAAGGATCCACTTCAAAGTACAAATTCCATTTCG LNU214_NR_XhoI (SEQ IN NO: 4916) AAACTCGAGCCACAGTAAACAAAGCATTCAAATC LNU214_ER_XhoI (SEQ IN NO: 4917) AAACTCGAGACCCAAACTCGAACAATTTACC LNU215 BamHI, XhoI LNU215_EF_BamHI (SEQ IN NO: 4918) AAAGGATCCTTCCTGAGAAAGAAAGCGAAAC LNU215_ER_XhoI (SEQ IN NO: 4919) AAACTCGAGTCCAATCCCATAAGAACTGAGC LNU216 BamHI, KpnI LNU216_F_BamHI (SEQ IN NO: 4920) AAAGGATCCACCCAAGCTCACACATCTCC LNU216_F_BamHI (SEQ IN NO: 4920) AAAGGATCCACCCAAGCTCACACATCTCC LNU216_NR_KpnI (SEQ IN NO: 4921) AAAGGTACCATACGAGGAAACCATGACGAAC LNU216_ER_KpnI (SEQ IN NO: 4922) AAAGGTACCCGATTACCCGATTTGTGATTTC LNU217 BamHI, XhoI LNU217_NF_BamHI (SEQ IN NO: 4923) AAAGGATCCCGTTCGATCTCTCCCATATAATTC LNU217_EF_BamHI (SEQ IN NO: 4924) AAAGGATCCATCCATCACTCGTTCGATCTC LNU217_NR_XhoI (SEQ IN NO: 4925) AAACTCGAGCTAAATAAAGCATGGCAGACTGTGTC LNU217_ER_XhoI (SEQ IN NO: 4926) AAACTCGAGAGCTCCATCTATTCATTCGTGC LNU218 SalI, XbaI LNU218_NF_SalI (SEQ IN NO: 4927) AAAGTCGACAGAAATCTGACCGCAATAATGG LNU218_EF_SalI (SEQ IN NO: 4928) AAAGTCGACTCTACAGAGAAATCTGACCGCA LNU218_NR_XbaI (SEQ IN NO: 4929) AAATCTAGAGATGTATAGCAACAAGAGAAACAAACA LNU218_ER_XbaI (SEQ IN NO: 4930) AAATCTAGAGAATGATGTATAGCAACAAGAGAAACA LNU219 BamHI, XhoI LNU219_EF_BamHI (SEQ IN NO: 4931) AAAGGATCCGATGAAGAAGACATCAATGACTGG LNU219_EF_BamHI (SEQ IN NO: 4931) AAAGGATCCGATGAAGAAGACATCAATGACTGG LNU220 SalI, XbaI LNU220_NF_SalI (SEQ IN NO: 4932) AAAGTCGACAACCTCGAACTCGAAGCAGAG LNU220_EF_SalI (SEQ IN NO: 4933) AAAGTCGACGAGAGAGACACAAGCCAACCTC LNU220_NR_XbaI (SEQ IN NO: 4934) AAATCTAGAAACAACCACCTCCATCACGTAG LNU220_ER_XbaI (SEQ IN NO: 4935) AAATCTAGACATCCAGCCACTAAATCGTTG LNU223 XhoI, EcoRV LNU223_F_XhoI (SEQ IN NO: 4936) AAACTCGAGATTAGAAGCCTTCGGCTTTACG LNU223_F_XhoI (SEQ IN NO: 4936) AAACTCGAGATTAGAAGCCTTCGGCTTTACG LNU223_NR_EcoRV (SEQ IN NO: 4937) AAAGATATCTCTACCTGAGAAATGCTCCCTG LNU223_ER_EcoRV (SEQ IN NO: 4938) AAAGATATCGTGAATATCATGGGTTGACTGG LNU224 BamHI, KpnI LNU224_NF_BamHI (SEQ IN NO: 4939) AAAGGATCCATCAACTCGCGACGAATCAG LNU224_EF_BamHI (SEQ IN NO: 4940) AAAGGATCCGAACAGAGAAGAGCATCAACTCG LNU224_NR_KpnI (SEQ IN NO: 4941) AAAGGTACCTATCCCTTGAGTTATTGCCTCG LNU224_ER_KpnI (SEQ IN NO: 4942) AAAGGTACCTCCTGCTACAATGCTATCCACC LNU225 BamHI, KpnI LNU225_NF_BamHI (SEQ IN NO: 4943) AAAGGATCCTCGGTAAGATTTCTTGGAGCAG LNU225_EF_BamHI (SEQ IN NO: 4944) AAAGGATCCTTCCTCTTCATCATCGACATCC LNU225_NR_KpnI (SEQ IN NO: 4945) AAAGGTACCCTAGCATAACCACGAGAGAGAAAGAG LNU225_ER_KpnI (SEQ IN NO: 4946) AAAGGTACCCTAACAAATGCATAACCACGAGAGAG LNU228 SalI, XbaI LNU228_NF_SalI (SEQ IN NO: 4947) AAAGTCGACAACTCTTGCCACACGGGTC LNU228_EF_SalI (SEQ IN NO: 4948) AAAGTCGACAGAAACTCTTGCCACACAGCTC LNU228_NR_XbaI (SEQ IN NO: 4949) AAATCTAGACTATGTGTGTTTCTGCAGGACTTG LNU228_ER_XbaI (SEQ IN NO: 4950) AAATCTAGACTACGTACAAACTCTTATGGCGTGG LNU229 SalI, SacI LNU229_F_SalI (SEQ IN NO: 4951) TAAGTCGACAATTTAGCAATGCTCTGTTTCTCTC LNU229_ER_SacI (SEQ IN NO: 4952) ACAGAGCTCAATCATTGATAACACTAAAACTTTCTGC LNU23 BamHI, KpnI LNU23_EF_BamHI (SEQ IN NO: 4953) AAAGGATCCAAAGTCAGCGTGAGAGACTGG LNU23_ER_KpnI (SEQ IN NO: 4954) AAAGGTACCCCTTGACACTTCAGATCTATTCTGTG LNU230 BamHI, KpnI LNU230_F_BamHI (SEQ IN NO: 4955) TTCGGATCCACCACCCTCACACACGCT LNU230_F_BamHI (SEQ IN NO: 4955) TTCGGATCCACCACCCTCACACACGCT LNU230_NR_KpnI (SEQ IN NO: 4956) AAAGGTACCAAAGTACACCACAGTAGGCGAGA LNU230_ER_KpnI (SEQ IN NO: 4957) AAAGGTACCAAATATGACTGAATTAAGCAGCGAG LNU232 LNU232_NF_SalI (SEQ IN NO: 4958) AAAGTCGACACACACTTGGAAGCAAACAACC LNU232_NR_XbaI (SEQ IN NO: 4959) AAATCTAGAGAGACATACACTCCCACTGTCG LNU233 SalI, XbaI LNU233_EF_SalI (SEQ IN NO: 4960) AAAGTCGACGCGACCAGATCAGACTCCATC LNU233_ER_XbaI (SEQ IN NO: 4961) TTTTCTAGAGCTTCAAGCGATCCAGACC LNU234 SalI, BamHI LNU234_F_SalI (SEQ IN NO: 4962) AAAGTCGACACGTTGAACGATGGGAGC LNU234_ER_BamHI (SEQ IN NO: 4963) AAAGGATCCAGGGATGTAACATTCAACCACC LNU235 SalI, BamHI LNU235_F_SalI (SEQ IN NO: 4964) AAAGTCGACCACAATTCACCACCATGAACTC LNU235_ER_BamHI (SEQ IN NO: 4965) AAAGGATCCTGGAGCTAAACTTTATTGGTCACG LNU236 BamHI, XhoI LNU236_EF_BamHI (SEQ IN NO: 4966) AAAGGATCCTTAACTGCTTGCCCGTTCAT LNU236_ER_XhoI (SEQ IN NO: 4967) AAACTCGAGGTCTAGAGAGGGAGACGATTGC LNU239 BamHI, XhoI LNU239_EF_BamHI (SEQ IN NO: 4968) AAAGGATCCGTTCCTCCTCCTACCTTTGGTC LNU239_ER_XhoI (SEQ IN NO: 4969) AAACTCGAGATGTCCCGTCAACTGAAACAAC LNU24 BamHI, XhoI LNU24_NF_BamHI (SEQ IN NO: 4970) AAAGGATCCCCTCTGGTCCTCCATCAGATAC LNU24_EF_BamHI (SEQ IN NO: 4971) AAAGGATCCCTACTTGCTGCTTGGCGTAGAC LNU24_NR_XhoI (SEQ IN NO: 4972) AAACTCGAGTGTGACGGTGCTAAAGACAATC LNU24_ER_XhoI (SEQ IN NO: 4973) AAACTCGAGTTAGTTGCGAGGACATCAAATC LNU241 SalI, XbaI LNU241_NF2_SalI (SEQ IN NO: 4974) TTAGTCGACCTTCGATATCATGGCGTCC LNU241_EF2_SalI (SEQ IN NO: 4975) AATGTCGACTGTCCATATACACTCCTTGCACTC LNU241_NR2_XbaI (SEQ IN NO: 4976) TAATCTAGACGATCTACACAAGAATCAATGGACA LNU241_ER2_XbaI (SEQ IN NO: 4977) TAATCTAGAGCTCCATGGATGTATGAGACC LNU242 SalI, BamHI LNU242_F_SalI (SEQ IN NO: 4978) AAAGTCGACGAGAAAAATGTCCATTAGAGCTCAAG LNU242_F_SalI (SEQ IN NO: 4978) AAAGTCGACGAGAAAAATGTCCATTAGAGCTCAAG LNU242_NR_BamHI (SEQ IN NO: 4979) TTTGGATCCCTATATTAACACTACCTCAGCTTGGCT LNU242_ER_BamHI (SEQ IN NO: 4980) TGTGGATCCTGGTATATTCAAAGCCTAAAGATTCAG LNU243 SalI, XbaI LNU243_F_SalI (SEQ IN NO: 4981) AAAGTCGACGACGGGTCAATCATGGAGG LNU243_F_SalI (SEQ IN NO: 4981) AAAGTCGACGACGGGTCAATCATGGAGG LNU243_NR_XbaI (SEQ IN NO: 4982) AAATCTAGACTATCAGATCACCCTCAACCTTACC LNU243_ER_XbaI (SEQ IN NO: 4983) AAATCTAGAGGAGTACACACAACACAACACG LNU244 BamHI, EcoRV LNU244_NF_BamHI (SEQ IN NO: 4984) TTAGGATCCGGGAAGCGAGCATTATGGAC LNU244_EF_BamHI (SEQ IN NO: 4985) TTTGGATCCCCCTCCTTTCATTATTCTATCCG LNU244_NR_EcoRV (SEQ IN NO: 4986) AAAGATATCTGTTTCATCTGCACTACTTTACCTAGC LNU244_ER_EcoRV (SEQ IN NO: 4987) AAAGATATCGGCAAATAACCAAATGTCTCG LNU245 XhoI, SacI LNU245_EF_XhoI (SEQ IN NO: 4988) AAACTCGAGCATCATCTTCTTCTTCTTCTCATTGG LNU245_ER_SacI (SEQ IN NO: 4989) AATGAGCTCCTAGAGATACAACAGACATGTGATCATT G LNU246 BamHI, XhoI LNU246_F_BamHI (SEQ IN NO: 4990) AAAGGATCCATAATTTGGAATTGGGTTGCTG LNU246_ER_XhoI (SEQ IN NO: 4991) AAACTCGAGATGGTCTAACCAATATGGGACG LNU247 LNU247_EF_BamHI (SEQ IN NO: 4992) AAAGGATCCTCTTGCCCATTATTCTCCATTG LNU247_ER_KpnI (SEQ IN NO: 4993) AAAGGTACCTATCCGTCTGGTTGTTCATCG LNU249 XhoI, SacI LNU249_EF_XhoI (SEQ IN NO: 4994) AAACTCGAGGCTCTTGAATTCTCCCTCATACC LNU249_ER_SacI (SEQ IN NO: 4995) AAAGAGCTCGGCAACTTAGCATTTGTGATGC LNU25 BamHI, XhoI LNU25_EF_BamHI (SEQ IN NO: 4996) AAAGGATCCATTGACTAGAGCGGGAGGAAAG LNU25_ER_XhoI (SEQ IN NO: 4997) AAACTCGAGCAACAATTGCTAAATTCATGGTG LNU250 SalI, BamHI LNU250_NF_SalI (SEQ IN NO: 4998) AAAGTCGACTATCTCCACCGTTTGTTTGTTG LNU250_EF_SalI (SEQ IN NO: 4999) AAAGTCGACTTCATCATCATCGTATCTCCACC LNU250_NR_BamHI (SEQ IN NO: 5000) AAAGGATCCGGGTTTAATGGGTTAGTGAATTCTTC LNU250_ER_BamHI (SEQ IN NO: 5001) AAAGGATCCAACGCCAAATAACGCAAACTC LNU251 BamHI, XhoI LNU251_NF_BamHI (SEQ IN NO: 5002) AAAGGATCCCCGAGGAAACCCTAATTTCTTG LNU251_EF_BamHI (SEQ IN NO: 5003) AAAGGATCCGTTTGCTGTATCTCCTCCATCG LNU251_NR_XhoI (SEQ IN NO: 5004) AAACTCGAGGATAACGTTGACATGTTCCATTTG LNU251_ER_XhoI (SEQ IN NO: 5005) AAACTCGAGAAACCCTATCATCCAATTCAGG LNU253 BamHI, XhoI LNU253_EF_BamHI (SEQ IN NO: 5006) AAAGGATCCTATTCCGTGCAAACACAACAAC LNU253_ER_XhoI (SEQ IN NO: 5007) AAACTCGAGAACTGCACTTTCCCTCCTCTTC LNU254 BamHI, XhoI LNU254_NF_BamHI (SEQ IN NO: 5008) AAAGGATCCATTTCTTCTCGCACTCTTCACC LNU254_EF_BamHI (SEQ IN NO: 5009) AAAGGATCCCCCTCTAAATAGGGAGTGAGTGAG LNU254_R_XhoI (SEQ IN NO: 5010) AAACTCGAGAACTTCAAACTTCCCAACCAAAC LNU254_R_XhoI (SEQ IN NO: 5010) AAACTCGAGAACTTCAAACTTCCCAACCAAAC LNU255 SalI, BamHI LNU255_F_SalI (SEQ IN NO: 5011) AAAGTCGACAACAAACTTTAAACAATGGCTGG LNU255_F_SalI (SEQ IN NO: 5011) AAAGTCGACAACAAACTTTAAACAATGGCTGG LNU255_NR_BamHI (SEQ IN NO: 5012) AAAGGATCCGTTCTGGGTCAATGGTCGTATC LNU255_ER_BamHI (SEQ IN NO: 5013) AAAGGATCCTTATTGGATATGATTGGCCCAC LNU256 BamHI, XhoI LNU256_F_BamHI (SEQ IN NO: 5014) AAAGGATCCGCTTGAAGCTTCCCACAACTAC LNU256_F_BamHI (SEQ IN NO: 5014) AAAGGATCCGCTTGAAGCTTCCCACAACTAC LNU256_NR_XhoI (SEQ IN NO: 5015) AAACTCGAGACGGCCTGATAAGCATTCAC LNU256_ER_XhoI (SEQ IN NO: 5016) AAACTCGAGGGAACATGTGACATAACAACAAGG LNU257 SalI, XbaI LNU257_EF_SalI (SEQ IN NO: 5017) TTAGTCGACACTACTATGTACAGATTCAGCAACACAG LNU257_ER_XbaI (SEQ IN NO: 5018) AAATCTAGACATATACTCATGCACTCGTAGCA LNU258 BamHI, KpnI LNU258_F_BamHI (SEQ IN NO: 5019) AAAGGATCCCCCACAAACAAACAAAATGGA LNU258_ER_KpnI (SEQ IN NO: 5020) AAAGGTACCAGCCCACTAACCCGGTG LNU260 BamHI, XhoI LNU260_NF_BamHI (SEQ IN NO: 5021) AAAGGATCCGAACAATCCCAAGATTCTCCTC LNU260_EF_BamHI (SEQ IN NO: 5022) AAAGGATCCGTTACACGCGTAGGCTAGTGG LNU260_NR_XhoI (SEQ IN NO: 5023) AAACTCGAGCACTCAAAGAGAAGAGTGACAGAGTG LNU260_ER_XhoI (SEQ IN NO: 5024) AAACTCGAGCATTCACTCAAAGAGAAGAGTGACAG LNU261 BamHI, XhoI LNU261_F_BamHI (SEQ IN NO: 5025) AATGGATCCTCCGAAACGAGAAAACAAACTATG LNU261_ER_XhoI (SEQ IN NO: 5026) TTTCTCGAGCCGATCAAGATTATTTCAGGACG LNU263 SalI, XbaI LNU263_NF_SalI (SEQ IN NO: 5027) AAAGTCGACTCTCAATCTCTCAATCCCGAGT LNU263_EF_SalI (SEQ IN NO: 5028) AAAGTCGACGGACTCAAGCTCACAATCACAA LNU263_R_XbaI (SEQ IN NO: 5029) AATTCTAGATTTCCAAGCTTATCTAGTGCATAACA LNU263_R_XbaI (SEQ IN NO: 5029) AATTCTAGATTTCCAAGCTTATCTAGTGCATAACA LNU266 BamHI, XhoI LNU266_NF_BamHI (SEQ IN NO: 5030) AAAGGATCCGAGGAGCTTATCCTGTGCAGC LNU266_EF_BamHI (SEQ IN NO: 5031) AAAGGATCCAACGGAGACCACGTGTGAG LNU266_NR_XhoI (SEQ IN NO: 5032) AAACTCGAGCGCTGCATTGTTTCAAGAATTAC LNU266_ER_XhoI (SEQ IN NO: 5033) AAACTCGAGTAATGAGTTTATAGCCCGCTGC LNU267 SalI, XbaI LNU267_NF_SalI (SEQ IN NO: 5034) AAAGTCGACGATTCCAGTCCTCCTCCTGTTC LNU267_EF_SalI (SEQ IN NO: 5035) AAAGTCGACGTCTGGTGTGTGGATGATTCC LNU267_NR_XbaI (SEQ IN NO: 5036) AAATCTAGAATCTTCCATCATCATGCGCTAC LNU267_ER_XbaI (SEQ IN NO: 5037) AAATCTAGATCCGAAATGCTTGTATCATGG LNU268 XhoI, EcoRV LNU268_F2_XhoI (SEQ IN NO: 5038) TATCTCGAGCATCCAATTCCACTTCCACAC LNU268_R2_EcoRV (SEQ IN NO: 5039) ATTGATATCCCACATTCAGATCCTCAGTGC LNU27 SalI, XbaI LNU27_F_SalI (SEQ IN NO: 5040) AAAGTCGACAGCAGAAGGGATCGGAGATG LNU27_ER_XbaI (SEQ IN NO: 5041) AAATCTAGACATGAAATGAACCTCAGCAGTC LNU271 BamHI, KpnI LNU271_EF_BamHI (SEQ IN NO: 5042) AAAGGATCCGCAGAATCGCAGTGCAGAC LNU271_ER_KpnI (SEQ IN NO: 5043) AAAGGTACCCACCAGAAATCACCAATGTGTC LNU274 SalI, XbaI LNU274_F_SalI (SEQ IN NO: 5044) AAAGTCGACTGATCGCCGTTGGATCTC LNU274_F_SalI (SEQ IN NO: 5044) AAAGTCGACTGATCGCCGTTGGATCTC LNU274_ER_XbaI (SEQ IN NO: 5045) AAATCTAGAATCTCTGGGTTGAGCGTTACTG LNU274_ER_XbaI (SEQ IN NO: 5045) AAATCTAGAATCTCTGGGTTGAGCGTTACTG LNU276 BamHI, KpnI LNU276_EF_BamHI (SEQ IN NO: 5046) AAAGGATCCACACAAGCATCTCCTCTTCTCC LNU276_ER_KpnI (SEQ IN NO: 5047) AAAGGTACCAGAAGTGTGTATTTGTGCCGTG LNU277 XhoI, EcoRV LNU277_NF_XhoI (SEQ IN NO: 5048) AAACTCGAGAAGGAATTTGTTTGTTGAAGCTG LNU277_EF_XhoI (SEQ IN NO: 5049) AAACTCGAGTTCGGTTCATCAAATCAGAAGG LNU277_NR_EcoRV (SEQ IN NO: 5050) AAAGATATCATTGCTGGTATCCTGAATCCTG LNU277_ER_EcoRV (SEQ IN NO: 5051) AAAGATATCAATGAAATCGTGTGCCAAATTC LNU278 LNU278_NF_SalI (SEQ IN NO: 5052) AAAGTCGACCCAAGAACACAACATCAAGAGC LNU278_EF_SalI (SEQ IN NO: 5053) AAAGTCGACCACCAGACCACTCAGAGAAGTG LNU278_NR_XbaI (SEQ IN NO: 5054) AAATCTAGATGAAACAAATAGAGTACCGCAGG LNU278_ER_XbaI (SEQ IN NO: 5055) AAATCTAGAATTATGCAGACCTGGAAGAAGC LNU279 SalI, XbaI LNU279_NF_SalI (SEQ IN NO: 5056) AAAGTCGACGCTTCAACACAACACTTCAGTAAATC LNU279_EF_SalI (SEQ IN NO: 5057) AAAGTCGACTATATGCGTCTGCTTCAACACAAC LNU279_R_XbaI (SEQ IN NO: 5058) AAATCTAGACATCAATCATTGGCTCATTGC LNU279_R_XbaI (SEQ IN NO: 5058) AAATCTAGACATCAATCATTGGCTCATTGC LNU28 SalI, XbaI LNU28_EF_SalI (SEQ IN NO: 5059) AAAGTCGACAGCTGAACCACAAGCAGTGAG LNU28_ER_XbaI (SEQ IN NO: 5060) AAATCTAGACACAGTAGGCACCGAAAGTATG LNU280 BamHI, XhoI LNU280_F_BamHI (SEQ IN NO: 5061) AAAGGATCCCCATCGCTTCGTTTCCAAG LNU280_F_BamHI (SEQ IN NO: 5061) AAAGGATCCCCATCGCTTCGTTTCCAAG LNU280_NR_XhoI (SEQ IN NO: 5062) AAACTCGAGATCGTTTCTTCCACTCCACTTC LNU280_ER_XhoI (SEQ IN NO: 5063) AAACTCGAGGTTACTTCTGGACTGCACAACG LNU284 BamHI, XhoI LNU284_NF_BamHI (SEQ IN NO: 5064) AAAGGATCCGCATAGTCTCTGGTGCAAGAATC LNU284_EF_BamHI (SEQ IN NO: 5065) AAAGGATCCGACAGCATAGTCTCTGGTGCAAG LNU284_NR_XhoI (SEQ IN NO: 5066) AAACTCGAGCAATTCTACAATGGGCCTTGAC LNU284_ER_XhoI (SEQ IN NO: 5067) AAACTCGAGTGATATATGTTAATGCTCACCCAATTC LNU287 BamHI, XhoI LNU287_EF_BamHI (SEQ IN NO: 5068) AAAGGATCCATTTATCGGGTCTCTTCCCAAC LNU287_ER_XhoI (SEQ IN NO: 5069) AAACTCGAGTGGATGCCTGTAGCTTGAATTAC LNU288 BamHI, XhoI LNU288_EF_BamHI (SEQ IN NO: 5070) AAAGGATCCGCAAAGTTGTAGCCAATGGAAG LNU288_ER_XhoI (SEQ IN NO: 5071) AAACTCGAGGCAAACTTGAGTTGCATTTGAC LNU289 BamHI, XhoI LNU289_EF_BamHI (SEQ IN NO: 5072) AAAGGATCCCCCTTCTCTCCATAACGAACC LNU289_ER_XhoI (SEQ IN NO: 5073) AAACTCGAGCTTCTTCTCGGGTTAAAGGGAC LNU29 BamHI, KpnI LNU29_F_BamHI (SEQ IN NO: 5074) TTTGGATCCTCATTATCATCAATATGGGTAGAGCTC LNU29_F_BamHI (SEQ IN NO: 5074) TTTGGATCCTCATTATCATCAATATGGGTAGAGCTC LNU29_NR_KpnI (SEQ IN NO: 5075) TTTGGTACCTTAACCTCTTTCGAACTGTTTGTTTG LNU29_ER_KpnI (SEQ IN NO: 5076) ACTGGTACCTTACAACATGTCCAAAAGCTCAGAG LNU3 SalI, XbaI LNU3_NF_SalI (SEQ IN NO: 5077) AAAGTCGACAACCACCTGCGATTCTGC LNU3_EF_SalI (SEQ IN NO: 5078) AAAGTCGACGTTCGTCCGCAACAAACC LNU3_NR_XbaI (SEQ IN NO: 5079) AAATCTAGACTAGAGCGGCAATATCATAGCAAAC LNU3_ER_XbaI(SEQ IN NO: 5080) AAATCTAGACTACATCCATGTACAAGCTAACATGC LNU33 BamHI, XhoI LNU33_EF_BamHI (SEQ IN NO: 5081) AAAGGATCCTGGCGGCTAAAGTTTGTGAG LNU33_ER_XhoI (SEQ IN NO: 5082) AAACTCGAGTTACACATGGAAGACCTGAACG LNU35 LNU35_NF_BamHI (SEQ IN NO: 5083) AAAGGATCCCGGTACAATAGCCGAATTTGAG LNU35_EF_BamHI (SEQ IN NO: 5084) AAAGGATCCAAGCCCAGCCGGTACAATAG LNU35_NR_XhoI (SEQ IN NO: 5085) AAACTCGAGGACTCCAATCAATCTACGGAGC LNU35_ER_XhoI (SEQ IN NO: 5086) AAACTCGAGTGGCACTTTCTAGCAGCCTAAC LNU36 BamHI, XhoI LNU36_EF_BamHI (SEQ IN NO: 5087) AAAGGATCCCCCAAACTCCCTTGTGAACTG LNU36_ER_XhoI (SEQ IN NO: 5088) AAACTCGAGTCTAATGTACAACACTGGGCAAAC LNU37 BamHI, XhoI LNU37_EF_BamHI (SEQ IN NO: 5089) AAAGGATCCACCAAGTCGCTCAAAGAAACTG LNU37_ER_XhoI (SEQ IN NO: 5090) AAACTCGAGGCACGGTACCTTCTTGTTCTTC LNU4 BamHI, XhoI LNU4_NF_BamHI (SEQ IN NO: 5091) AAAGGATCCAGATAGACCCGGAGGAAACAAG LNU4_EF_BamHI (SEQ IN NO: 5092) AAAGGATCCAGGCGCCAACTAATAACCAGAG LNU4 BamHI, XhoI LNU4_NR_XhoI (SEQ IN NO: 5093) AAACTCGAGCCCTAGAATAAGAACCACAAATCG LNU4_ER_XhoI (SEQ IN NO: 5094) AAACTCGAGTTCAGAAATTCAAATCACAGTTTCC LNU40 SalI, XbaI LNU40_EF_SalI (SEQ IN NO: 5095) AAAGTCGACACCACATATCATCGAGAGTTCG LNU40_ER_XbaI (SEQ IN NO: 5096) AAATCTAGACTTGGTCACTGGCTAGACCATC LNU43 BamHI, XhoI LNU43_EF_BamHI (SEQ IN NO: 5097) AAAGGATCCTCTCTCCGACCTAGCGAGAC LNU43_ER_XhoI (SEQ IN NO: 5098) AAACTCGAGTAATTTCAAGGTCTTGCCCAAC LNU44 SalI, XbaI LNU44_EF_SalI (SEQ IN NO: 5099) AAAGTCGACCTACCAACTCCGGCTTGTTC LNU44_ER_XbaI (SEQ IN NO: 5100) AAATCTAGACCTTCACACTGATCACTCGTTTC LNU45 SalI, XbaI LNU45_F_SalI (SEQ IN NO: 5101) AAAGTCGACCGCTTCTTTCTCACAATGGTTC LNU45_ER_XbaI (SEQ IN NO: 5102) AAATCTAGATGGCTACTATGCCTTGTGGAAG LNU46 BamHI, SalI LNU46_EF_SalI (SEQ IN NO: 5103) AAAGTCGACAGGTTGAAGAAGCAACACAAGC LNU46_ER_BamHI(SEQ IN NO: 5104) AAAGGATCCAACACTTCGAATCATGACCTCC LNU48 BamHI, XhoI LNU48_EF_BamHI (SEQ IN NO: 5105) AAAGGATCCGATATGGTACAACAACCGAGAGC LNU48_ER_XhoI (SEQ IN NO: 5106) AAACTCGAGGATCATCCCATTTCAAGAGAGC LNU5 BamHI, XhoI LNU5_NF_BamHI (SEQ IN NO: 5107) (6669) AAAGGATCCGCTCTCCACTGTCCACGAAC LNU5_EF_BamHI (SEQ IN NO: 5108) AAAGGATCCCCAGATTAGTTGGAAGCTTTCTCTTC LNU5_NR_XhoI(SEQ IN NO: 5109) AAACTCGAGTCATCATCTTCCATTGCTCTACC LNU5_ER_XhoI(SEQ IN NO: 5110) AAACTCGAGTTCCTTTCATTATTTGCCAACG LNU5 BamHI, XhoI LNU5_NF_BamHI (SEQ IN NO: 5107) (Root_P_F) AAAGGATCCGCTCTCCACTGTCCACGAAC LNU5_EF_BamHI (SEQ IN NO: 5108) AAAGGATCCCCAGATTAGTTGGAAGCTTTCTCTTC LNU5_NR_XhoI (SEQ IN NO: 5109) AAACTCGAGTCATCATCTTCCATTGCTCTACC LNU5_ER_XhoI (SEQ IN NO: 5110) AAACTCGAGTTCCTTTCATTATTTGCCAACG LNU50 SalI, XbaI LNU50_NF_SalI (SEQ IN NO: 5111) AAAGTCGACAGAACTGATAAGGCCAGTGTCG LNU50_EF_SalI (SEQ IN NO: 5112) AAAGTCGACCGCGGTTAAGTTAGTTGTTGTTG LNU50_NR_XbaI (SEQ IN NO: 5113) AAATCTAGATCCTATGTGTTGTTTAGCTACCAGG LNU50_ER_XbaI (SEQ IN NO: 5114) AAATCTAGATTCGCATTTAAATAACTGTGCTG LNU52 XhoI, EcoRV LNU52_NF_XhoI (SEQ IN NO: 5115) AAACTCGAGGGTGGGTGTTGCTTGTACC LNU52_NR_EcoRV (SEQ IN NO: 5116) AAAGATATCCCTCACCAGGTAGGTAGTCTGC LNU53 BamHI, XhoI LNU53_NF_BamHI (SEQ IN NO: 5117) AAAGGATCCGAGTGAATTAGAGAAAGGCAAATGG LNU53_EF_BamHI (SEQ IN NO: 5118) AAAGGATCCATCGAGTGAATTAGAGAAAGGCA LNU53_R_XhoI (SEQ IN NO: 5119) AGTCTCGAGTTATGGAAGTTATGAAATACAAGCAGG LNU53_R_XhoI (SEQ IN NO: 5119) AGTCTCGAGTTATGGAAGTTATGAAATACAAGCAGG LNU54 SalI, XbaI LNU54_EF_SalI (SEQ IN NO: 5120) AAAGTCGACCAGTTGGCCTTATCCGTATCTC LNU54_R_XbaI (SEQ IN NO: 5121) AAATCTAGAATCCTTGAATCCAAATGAAACG LNU55 BamHI, XhoI LNU55_F_BamHI (SEQ IN NO: 5122) AAAGGATCCTGTTAGGGAAGAAGTACTGAAGGTG LNU55_F_BamHI (SEQ IN NO: 5122) AAAGGATCCTGTTAGGGAAGAAGTACTGAAGGTG LNU55_NR_XhoI (SEQ IN NO: 5123) AAACTCGAGGAGGACCAGTTGAATGCCTC LNU55_ER_XhoI (SEQ IN NO: 5124) AAACTCGAGACAGAACTCTAGACTCATGAGGACC LNU56 SalI, XbaI LNU56_EF_SalI (SEQ IN NO: 5125) AAAGTCGACACATAACACCTCAAATTCTGTGATTC LNU56_ER_XbaI (SEQ IN NO: 5126) AAATCTAGATGGAGTACACAACAGATGGCTG LNU57 SalI, XbaI LNU57_NF_SalI (SEQ IN NO: 5127) AAAGTCGACCTGAGGGACTGTTCCAGCTC LNU57_EF_SalI (SEQ IN NO: 5128) AAAGTCGACACACAAGAAACACCTGAGGGAC LNU57_NR_XbaI (SEQ IN NO: 5129) AAATCTAGACTATTTATTATCACAGCCATCCATCG LNU57_ER_XbaI (SEQ IN NO: 5130) AAATCTAGACTATTGGCAGGCACACTGATATG LNU58 LNU58_NF_SalI (SEQ IN NO: 5131) AAAGTCGACCCAAGCTAACGAGCAGTAGCAC LNU58_EF_SalI (SEQ IN NO: 5132) AAAGTCGACGATAGCCAAGCTAACGAGCAGTAG LNU58_NR_XbaI (SEQ IN NO: 5133) AAATCTAGAGTTCTTCTTCGTGGTTTCCAAC LNU58_ER_XbaI (SEQ IN NO: 5134) AAATCTAGAAGACCAGAAACATCTCCGTTTG LNU6 BamHI, XhoI LNU6_NF_BamHI (SEQ IN NO: 5135) AAAGGATCCCAACACCGCTCATCTTCTCTTC LNU6_NR_XhoI (SEQ IN NO: 5136) AAACTCGAGCAACCGAAGGTGCTTATCGTC LNU60 LNU60_NF_BamHI (SEQ IN NO: 5137) AAAGGATCCACTCTGAACTGAAGCGAAGTCC LNU60_NF_BamHI (SEQ IN NO: 5137) AAAGGATCCACTCTGAACTGAAGCGAAGTCC LNU60_NR_XhoI (SEQ IN NO: 5138) AAACTCGAGTCTTCTCTGTTGCTGGAGAAGC LNU60_NR_XhoI (SEQ IN NO: 5138) AAACTCGAGTCTTCTCTGTTGCTGGAGAAGC LNU61 LNU61_NF_BamHI (SEQ IN NO: 5139) AAAGGATCCCCATTATATTGCTCGCGAGTTC LNU61_NR_XhoI (SEQ IN NO: 5140) AAACTCGAGCAGTAGCATCAAAGAAACCATCG LNU63 SalI, XbaI LNU63_EF_SalI (SEQ IN NO: 5141) AAAGTCGACGATCTTATCCTCGGCGAAGC LNU63_ER_XbaI (SEQ IN NO: 5142) AAATCTAGAGCAGTAGGGATGTGTCAACAAG LNU64 BamHI, XhoI LNU64_NF_BamHI (SEQ IN NO: 5143) AAAGGATCCTACCCTGTCTCTCCTCCAGC LNU64_NR_XhoI (SEQ IN NO: 5144) AAACTCGAGATTTCTGCGTACACCAAGAACC LNU65 BamHI, XhoI LNU65_F_BamHI (SEQ IN NO: 5145) AAAGGATCCATTTCCTCCTTCCCTTGCAC LNU65_ER_XhoI (SEQ IN NO: 5146) AAACTCGAGAGGCATTTGAAACTGGTTGATG LNU67 LNU67_F_XhoI (SEQ IN NO: 5147) AAACTCGAGTTACTCTCTCCGCCCTCCTAAAC LNU67_F_XhoI (SEQ IN NO: 5147) AAACTCGAGTTACTCTCTCCGCCCTCCTAAAC LNU67_NR_SacI (SEQ IN NO: 5148) AAAGAGCTCCTGTTATTATGTGCTGCCAACG LNU67_ER_SacI (SEQ IN NO: 5149) AAAGAGCTCAGGAGTTCACCTTGGAGATCAG LNU68 BamHI, KpnI LNU68_EF_BamHI (SEQ IN NO: 5150) AAAGGATCCTATACAGCCTAGAACAACTGCTTGC LNU68_ER_KpnI (SEQ IN NO: 5151) AAAGGTACCTCATGTCAGTATCTCAGGCGTC LNU69 BamHI, XhoI LNU69_EF_BamHI (SEQ IN NO: 5152) AAAGGATCCCAGCAGCAGCTAGGGTTTAGAG LNU69_ER_XhoI (SEQ IN NO: 5153) AAACTCGAGAACAATGAAGATGGTCTCAATGC LNU7 SalI, XbaI LNU7_F_SalI (SEQ IN NO: 5154) AAAGTCGACGAACTGCACCTTCACCTTCC LNU7_ER_XbaI (SEQ IN NO: 5155) AAATCTAGAGGT CTTCAGCAGAAACCAGG LNU70 SalI, XbaI LNU70_NF_SalI_Jap (SEQ IN NO: 5156) AAAGTCGACATTCCACTCCACCTCGTCC LNU70_EF_SalI_Jap (SEQ IN NO: 5157) AAAGTCGACAATCCACTACTATTCCACTCCACC LNU70_NR_XbaI_Jap (SEQ IN NO: 5158) AAATCTAGACGGCAGTAGAGAAGTGCTATTG LNU70_ER_XbaI_Jap (SEQ IN NO: 5159) AAATCTAGAGCAATTTGGCATGGTAATGAG LNU71 BamHI, KpnI LNU71_NF_BamHI (SEQ IN NO: 5160) AAAGGATCCTTCTCTCGTCTCGGCTCAAG LNU71_EF_BamHI (SEQ IN NO: 5161) AAAGGATCCCAAGTCTCGTGCTCTCACTCTC LNU71_NR_KpnI (SEQ IN NO: 5162) AAAGGTACCGCATGTGAATTACGAACCACAG LNU71_ER_KpnI (SEQ IN NO: 5163) AAAGGTACCAACGAAATTGTTGCTGGGATAG LNU72 BamHI, XhoI LNU72_NF_BamHI (SEQ IN NO: 5164) AAAGGATCCGTTGGTCACCACCCAAACTC LNU72_NR_XhoI (SEQ IN NO: 5165) AAACTCGAGGCACTGGAGTACTGGACAAGTG LNU73 XhoI, SacI LNU73_EF_XhoI (SEQ IN NO: 5166) AAACTCGAGACATATACACACCGGGCCAC LNU73_ER_SacI (SEQ IN NO: 5167) AAAGAGCTCCAAATGTTGCGTCGATCAAG LNU74 SalI, XbaI LNU74_NF_SalI (SEQ IN NO: 5168) AAAGTCGACGCATCTTCCTTAGCTCGCTC LNU74_EF_SalI (SEQ IN NO: 5169) AAAGTCGACATTTCTGCATCTTCCTTAGCTCG LNU74_NR_XbaI (SEQ IN NO: 5170) AAATCTAGACTGGCCAGGTAAGAGTGACTTG LNU74_ER_XbaI (SEQ IN NO: 5171) AAATCTAGATGATCCACTAAGTAGCAGAACAAGG LNU76 BamHI, KpnI LNU76_EF_BamHI (SEQ IN NO: 5172) AAAGGATCCAAATCATCAGCACAAGATCGAG LNU76_ER_KpnI (SEQ IN NO: 5173) AAAGGTACCCTACAATAGGATTAATTTGCCGCTG LNU79 XhoI, EcoRV LNU79_EF_XhoI (SEQ IN NO: 5174) AAACTCGAGACGAGAATCGCTGAACCTCA LNU79_R_EcoRV (SEQ IN NO: 5175) AAAGATATCAAGGAATCAAACTCCAGTTCTCAA LNU8 SalI, XbaI LNU8_F_SalI (SEQ IN NO: 5176) AAAGTCGACGGAAAAGAAGAGCTCAAGAAGAA LNU8_F_SalI (SEQ IN NO: 5176) AAAGTCGACGGAAAAGAAGAGCTCAAGAAGAA LNU8_NR_XbaI (SEQ IN NO: 5177) TTTTCTAGATCATGAGAGACCCACTTGAGGAG LNU8_ER_XbaI (SEQ IN NO: 5178) TATTCTAGATCAATTGTATGAGAGACCCACTTG LNU81 SalI, XbaI LNU81_NF_SalI (SEQ IN NO: 5179) AAAGTCGACGGGACTGTTGAAGCTCTGC LNU81_EF_SalI (SEQ IN NO: 5180) AAAGTCGACGAAACACCTGAGGGACTGTTG LNU81_NR_XbaI (SEQ IN NO: 5181) AAATCTAGAACAGCACTGGTGGTTGAAGAAC LNU81_ER_XbaI (SEQ IN NO: 5182) AAATCTAGAAATTACAGCCATCCATCCAATC LNU82 BamHI, XhoI LNU82_NF_BamHI (SEQ IN NO: 5183) AAAGGATCCGAACACGCTCTCTTCCAAAGC LNU82_EF_BamHI (SEQ IN NO: 5184) AAAGGATCCGAAGAACAAGACGAACACGCTC LNU82_NR_XhoI (SEQ IN NO: 5185) AAACTCGAGAGGCTACCAATCCACATCAGAC LNU82_ER_XhoI (SEQ IN NO: 5186) AAACTCGAGTATTCCAATCCAATCAACCAGG LNU83 BamHI, KpnI LNU83_F_BamHI (SEQ IN NO: 5187) AAAGGATCCGAAGGAGGCAATGGCTCG LNU83_ER_KpnI (SEQ IN NO: 5188) AAAGGTACCAGGAGCTCGACTCAAACATCTG LNU84 BamHI, KpnI LNU84_F_BamHI (SEQ IN NO: 5189) TTAGGATCCGAGCCCCATTCCATTCTTC LNU84_F_BamHI (SEQ IN NO: 5189) TTAGGATCCGAGCCCCATTCCATTCTTC LNU84_NR_KpnI (SEQ IN NO: 5190) AAAGGTACCCCAGCCAGGATCAGATCAAG LNU84_ER_KpnI (SEQ IN NO: 5191) TTAGGTACCATTTCCTTGTCAGGTCCAGC LNU85 SalI, XbaI LNU85_EF_SalI (SEQ IN NO: 5192) AAAGTCGACATTTGGGACATCGTCTCCTTC LNU85_ER_XbaI (SEQ IN NO: 5193) AAATCTAGAAAACAAACAAGGCAGAGTCCAC LNU86 BamHI, XhoI LNU86_NF_BamHI (SEQ IN NO: 5194) AAAGGATCCGGGACAGGACTGTTGGAAGTC LNU86_EF_BamHI (SEQ IN NO: 5195) AAAGGATCCAGCACACGTTCGTCTTCCTC LNU86_NR_XhoI (SEQ IN NO: 5196) AAACTCGAGCAGTGTTGTGGTAATGAGGTCG LNU86_ER_XhoI (SEQ IN NO: 5197) AAACTCGAGACTCAAGTGGCTCTCTCAGGAC LNU87 SalI, XbaI LNU87_EF_SalI (SEQ IN NO: 5198) AAAGTCGACGATTTGAAGCTCCCAGTTCTTG LNU87_ER_XbaI (SEQ IN NO: 5199) AAATCTAGACTACAATGAAATGAAATCCTGGAAGG LNU89 BamHI, XhoI LNU89_NF_BamHI (SEQ IN NO: 5200) AAAGGATCCCAACTCGAAAGGCTCCATTG LNU89_EF_BamHI (SEQ IN NO: 5201) AAAGGATCCGGTCTCCTCATCGAGTCCAAC LNU89_NR_XhoI (SEQ IN NO: 5202) AAACTCGAGCCGCAGCCAGGATTATATCAC LNU89_ER_XhoI (SEQ IN NO: 5203) AAACTCGAGCTTCAGCTTTGGAGAGCAACC LNU9 SalI, XbaI LNU9_NF_SalI (SEQ IN NO: 5204) AAAGTCGACCGTGAGGTTAACAACAAGAACAAG LNU9_EF_SalI (SEQ IN NO: 5205) AAAGTCGACCAATTGCCAAGTACTCTCTGAGC LNU9_NR_XbaI (SEQ IN NO: 5206) AAATCTAGATCAGCACTGTCCATTCAGGTAG LNU9_ER_XbaI (SEQ IN NO: 5207) AAATCTAGACTCACGCTTGGATTGGATTAC LNU94 SalI, SacI LNU94_NF_SalI (SEQ IN NO: 5208) TTTGTCGACTTAGGCATTATGGCTGTGGG LNU94_EF_SalI (SEQ IN NO: 5209) TTTGTCGACTTTGAACCAATTTTAGGCATTATGG LNU94_NR_SacI (SEQ IN NO: 5210) TTCGAGCTCTCATTTAATGATCTCATGCTTCTCC LNU94_ER_SacI (SEQ IN NO: 5211) TTCGAGCTCTGCAACAAACAAGCTTACACAATAC LNU95 BamHI, XhoI LNU95_NF_BamHI (SEQ IN NO: 5212) AAAGGATCCAGAAACCTCGACCCATTTCAG LNU95_EF_BamHI (SEQ IN NO: 5213) AAAGGATCCCCTCCAAATTGTAATCTAAACCTGC LNU95_NR_XhoI (SEQ IN NO: 5214) AAACTCGAGCAAACACCACTCATGACTCCAC LNU95_ER_XhoI (SEQ IN NO: 5215) AAACTCGAGTTCTCCCAGCAAACTTTCTCAC LNU96 SalI, XbaI LNU96_EF_SalI (SEQ IN NO: 5216) AAAGTCGACCGGTTCGTCTAGTCGTCTTCC LNU96_ER_XbaI (SEQ IN NO: 5217) AAATCTAGAAGCTCAGAGAAAGCAGGTTCAG LNU98 BamHI, KpnI LNU98_NF_BamHI (SEQ IN NO: 5218) AAAGGATCCGAAGCGACTCCAAGAAGCAG LNU98_EF_BamHI (SEQ IN NO: 5219) AAAGGATCCCTCGTCTGTGTCTGCCTACTCC LNU98_NR_KpnI (SEQ IN NO: 5220) AAAGGTACCTGACACCATTCAGACCAAAGTG LNU98_ER_KpnI (SEQ IN NO: 5221) AAAGGTACCCCATGTCCTGGAAATATGTCTG Provided are the PCR primers used for cloning the genes of some embodiments of the invention. Fwd = forward primer; Rev = reverse primer; Nested = nested primer for PCR (internal primer); External = external primer for PCR. NF = nested forward; EF-external forward; NR-nested reverse; ER-external reverse.

TABLE 59 Genes cloned from cDNA libraries or genomic DNA in a High copy number plasmid Gene Name High copy plasmid Amplified from Polynucleotide Polypeptide Organism Origin Organism Origin SEQ ID NO: SEQ ID NO: LNU1 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 258 707 LNU10 Topo B RICE Oryza sativa L. Indica Lebbonet cDNA 267 477 LNU100 pKS(Pks_J) COTTON Gossypium hirsutum ND cDNA 331 735 LNU101 pKS(Pks_J) RICE Oryza sativa L.Japonica LEMONT cDNA 332 736 LNU104 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 58-261 cDNA 333 737 LNU105 pKS(Pks_J) WHEAT Triticum aestivum L. cDNA 334 738 LNU106 pGXN (pKG + Nos + 35S) WHEAT Triticum aestivum L. ND cDNA 335 739 LNU107 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 336 547 LNU109 pKS(Pks_J) RICE Oryza sativa L. Indica Lebbonet cDNA 337 548 LNU11 GeneArt 268 478 LNU110 pKS(Pks_J) RICE Oryza sativa L. Indica TEBBONET cDNA 338 549 LNU112 GeneArt 339 550 LNU113 pKS(Pks_J) MAIZE Zea mays L. OH43 cDNA 340 740 LNU114 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica ND cDNA 341 552 LNU115 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 342 553 LNU116 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 343 554 LNU117 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 344 555 LNU118 pKS(Pks_J) RICE Oryza sativa L. Indica TEBBONET cDNA 345 556 LNU119 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 346 557 LNU12 pKS(Pks_J) RICE Oryza sativa L. Indica Lebbonet cDNA 269 709 LNU120 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica LEMONT cDNA 347 558 LNU121 pGXNa RICE Oryza sativa L. Japonica Nipponbare cDNA 348 559 LNU122 Topo B RICE Oryza sativa L. Indica Lebbonet cDNA 349 560 LNU123 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 350 741 LNU124 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 351 562 LNU125 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara Genomic 466 — LNU126 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 352 563 LNU127 GeneArt 353 564 LNU128 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 354 742 LNU129 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 355 743 LNU13 GeneArt 270 480 LNU130 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 356 744 LNU131 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 357 568 LNU132 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 358 569 LNU133 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 359 745 LNU134 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 360 746 LNU135 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 361 747 LNU136 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Columbia wt cDNA 362 573 LNU138 pKS(Pks_J) BARLEY Hordeum vulgare L. Manit cDNA 363 574 LNU14 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 271 710 LNU140 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 364 748 LNU141 pKS(Pks_J) WHEAT Triticum aestivum L. cDNA 365 749 LNU142 GeneArt 366 577 LNU143 pKS(Pks_J) COTTON Gossypium hirsutum ND cDNA 367 750 LNU147 pKS(Pks_J) COTTON Gossypium hirsutum Akala cDNA 368 580 LNU148 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 369 695 LNU149 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 370 751 LNU15 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 272 711 LNU150 pGXN (pKG + Nos + 35S) COTTON Gossypium hirsutum ND cDNA 371 752 LNU153 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 372 753 LNU154 pKS(Pks_J) COTTON Gossypium hirsutum ND cDNA 373 754 LNU155 pGXN (pKG + Nos + 35S) COTTON Gossypium hirsutum ND cDNA 374 755 LNU157 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 58-261 cDNA 375 587 LNU158 pKS(Pks_J) COTTON Gossypium hirsutum Akala cDNA 376 588 LNU161 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 58-261 cDNA 377 589 LNU168 pGXNa SORGHUM Sorghum bicolor ND cDNA 378 590 LNU17 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 273 483 LNU170 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 379 756 LNU171 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 380 757 LNU172 pKS(Pks_J) BARLEY Hordeum vulgare L. Manit cDNA 381 758 LNU173 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. ND cDNA 382 594 LNU175 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 383 595 LNU176 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica ND cDNA 384 759 LNU177 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 385 597 LNU178 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 386 598 LNU179 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 387 760 LNU180 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 388 600 LNU181 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 389 761 LNU182 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana ND cDNA 390 602 LNU183 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 391 603 LNU184 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana ND cDNA 392 604 LNU185 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 393 605 LNU186 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 394 606 LNU187 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 395 762 LNU188 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 396 608 LNU189 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 397 609 LNU19 pGXNa RICE Oryza sativa L. Japonica Nipponbare cDNA 274 484 LNU190 GeneArt 398 610 LNU191 GeneArt 399 611 LNU192 GeneArt 400 612 LNU196 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 401 613 LNU198 GeneArt 402 614 LNU2 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 259 469 LNU20 pGXN (pKG + Nos + 35S) TOMATO Lycopersicum esculentum M82 cDNA 275 485 LNU200 pGXNa TOMATO Lycopersicum esculentum M82 cDNA 403 615 LNU201 GeneArt 215 — LNU206 GeneArt 404 617 LNU207 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 405 618 LNU210 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 406 763 LNU211 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 407 620 LNU212 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 408 764 LNU213 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Columbia wt cDNA 409 622 LNU214 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 410 765 LNU215 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 411 624 LNU216 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 412 625 LNU217 pKS(Pks_J) RICE Oryza sativa L. Indica TEBBONET cDNA 413 626 LNU218 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 414 627 LNU219 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 415 766 LNU220 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica LEMONT cDNA 416 767 LNU222_H6 GeneArt 465 680 LNU223 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 417 631 LNU224 pKS(Pks_J) BARLEY Hordeum vulgare L. ND cDNA 418 632 LNU225 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 419 768 LNU228 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 420 634 LNU229 pGXN (pKG + Nos + 35S) TOMATO Lycopersicum esculentum M82 cDNA 421 635 LNU23 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Columbia wt cDNA 276 486 LNU230 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 422 636 LNU232 Topo B RICE Oryza sativa L. Japonica LEMONT cDNA 423 769 LNU233 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica ND Genomic 467 — LNU234 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 424 638 LNU235 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 425 770 LNU236 pKS(Pks_J) COTTON Gossypium hirsutum Akala cDNA 426 771 LNU239 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 427 641 LNU24 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 277 487 LNU241 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica LEMONT cDNA 428 643 LNU242 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Columbia wt cDNA 429 644 LNU243 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 430 645 LNU244 pKS(Pks_J) BARLEY Hordeum vulgare L. Manit cDNA 431 772 LNU245 pGXNa TOMATOLycopersicum esculentum M82 cDNA 432 773 LNU246 pKS(Pks_J) TOMATO Lycopersicum esculentum M82 cDNA 433 648 LNU247 Topo B ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 434 774 LNU249 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Columbia wt cDNA 435 650 LNU25 pKS(Pks_J) SORGHUM Sorghum bicolor ND cDNA 278 488 LNU250 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 436 775 LNU251 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 437 776 LNU253 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 438 777 LNU254 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 439 654 LNU255 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 440 778 LNU256 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 441 779 LNU257 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 442 657 LNU258 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 443 780 LNU260 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 444 781 LNU261 pKS(Pks_J) ARABIDOPSIS Arabidopsis thaliana Kondara cDNA 445 782 LNU262 GeneArt 446 661 LNU263 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 447 662 LNU265 GeneArt 448 663 LNU266 pKS(Pks_J) MAIZE Zea mays L. OH43 cDNA 449 783 LNU267 pGXN (pKG + Nos + 35S) MAIZE Zea mays L. B73 cDNA 450 665 LNU268 pKS(Pks_J) MAIZE Zea mays L. OH43 cDNA 451 666 LNU27 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 279 489 LNU271 pKS(Pks_J) RICE Oryza sativa L. Indica TEBBONET cDNA 452 667 LNU274 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica LEMONT cDNA 453 668 LNU275 GeneArt 454 669 LNU276 pKS(Pks_J) RICE Oryza sativa L. Indica TEBBONET cDNA 455 784 LNU277 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 456 671 LNU278 Topo B SORGHUM Sorghum bicolor ND cDNA 457 672 LNU279 pGXN (pKG + Nos + 35S) SORGHUM Sorghum bicolor ND cDNA 458 673 LNU28 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 280 712 LNU280 pKS(Pks_J) SORGHUM Sorghum bicolor ND cDNA 459 674 LNU282 GeneArt 460 675 LNU284 pKS(Pks_J) SOYBEAN Glycine max 40-219 cDNA 461 676 LNU287 pKS(Pks_J) SOYBEAN Glycine max 40-219 cDNA 462 677 LNU288 pKS(Pks_J) TOMATO Lycopersicum esculentum M82 cDNA 463 678 LNU289 pKS(Pks_J) TOMATO Lycopersicum esculentum M82 cDNA 464 679 LNU29 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 281 491 LNU3 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica LEMONT cDNA 260 470 LNU32 GeneArt 282 492 LNU33 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 283 713 LNU35 Topo B WHEAT Triticum aestivum L. ND cDNA 284 714 LNU36 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 285 715 LNU37 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 286 497 LNU4 pKS(Pks_J) BARLEY Hordeum vulgare L. Manit cDNA 261 708 LNU40 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica PECOS + cDNA 287 498 RICE Oryza sativa L. Japonica LEMONT LNU43 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 288 499 LNU44 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 58-261 cDNA 289 500 LNU45 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 58-261 cDNA 290 501 LNU46 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 291 502 LNU48 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 292 503 LNU5 pKS(Pks_J) BARLEY Hordeum vulgare L. ND cDNA 262 472 LNU50 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica ND cDNA 293 504 LNU51 GeneArt 294 505 LNU52 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 295 506 LNU53 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 296 716 LNU54 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 58-261 cDNA 297 717 LNU55 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 298 718 LNU56 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 40-219 cDNA 299 510 LNU57 pGXN (pKG + Nos + 35S) WHEAT Triticum aestivum L. ND cDNA 300 511 LNU58 Topo B WHEAT Triticum aestivum L. ND cDNA 301 719 LNU59 GeneArt 302 513 LNU6 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 263 473 LNU60 Topo B WHEAT Triticum aestivum L. ND cDNA 303 514 LNU61 Topo B WHEAT Triticum aestivum L. ND cDNA 304 720 LNU63 pGXN (pKG + Nos + 35S) WHEAT Triticum aestivum L. ND cDNA 305 516 LNU64 pKS(Pks_J) WHEAT Triticum aestivum L. ND cDNA 306 721 LNU65 pKS(Pks_J) RICE Oryza sativa L. Japonica ND cDNA 307 722 LNU67 Topo B RICE Oryza sativa L. Japonica ND cDNA 308 723 LNU68 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 309 520 LNU69 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 310 521 LNU7 pGXN (pKG + Nos + 35S) SOYBEAN Glycine max 40-219 cDNA 264 474 LNU70 pGXN (pKG + Nos + 35S) RICEOryza sativa L. Japonica LEMONT cDNA 311 724 LNU71 pKS(Pks_J) RICE Oryza sativa L. Japonica Nipponbare cDNA 312 523 LNU72 pKS(Pks_J) BARLEY Hordeum vulgare L. Manit cDNA 313 725 LNU73 pGXNa RICE Oryza sativa L. Indica TEBBONET cDNA 314 525 LNU74 pGXN (pKG + Nos + 35S) POPLAR Populus ND ND cDNA 315 726 LNU75 GeneArt 316 527 LNU76 pKS(Pks_J) RICE Oryza sativa L. Indica TEBBONET cDNA 317 528 LNU79 pKS(Pks_J) COTTON Gossypium hirsutum ND cDNA 318 727 LNU8 pGXN (pKG + Nos + 35S) ARABIDOPSIS Arabidopsis thaliana Columbia wt cDNA 265 475 LNU81 pGXN (pKG + Nos + 35S) BARLEY Hordeum vulgare L. Manit cDNA 319 728 LNU82 pKS(Pks_J) RICE Oryza sativa L. Japonica LEMONT cDNA 320 531 LNU83 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 321 532 LNU84 pKS(Pks_J) SORGHUM Sorghum bicolor ND cDNA 322 729 LNU85 pGXN (pKG + Nos + 35S) SORGHUM Sorghum bicolor ND cDNA 323 534 LNU86 pKS(Pks_J) MAIZE Zea mays L. OH43 cDNA 324 730 LNU87 pGXN (pKG + Nos + 35S) SORGHUM Sorghum bicolor ND cDNA 325 731 LNU89 pKS(Pks_J) WHEAT Triticum aestivum L. cDNA 326 732 LNU9 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica ND cDNA 266 476 LNU94 pGXN (pKG + Nos + 35S) TOMATO Lycopersicum esculentum M82 cDNA 327 538 LNU95 pKS(Pks_J) SOYBEAN Glycine max 58-261 cDNA 328 539 LNU96 pGXN (pKG + Nos + 35S) RICE Oryza sativa L. Japonica LEMONT cDNA 329 733 LNU98 pKS(Pks_J) MAIZE Zea mays L. B73 cDNA 330 734 Table 59. “Polyn.”—Polynucleotide; “Polyp.”—polypeptide.

Example 12 Transforming Agrobacterium tumefaciens Cells with Binary Vectors Harboring Putative Genes

Each of the binary vectors described in Example 11 above were used to transform Agrobacterium cells. Two additional binary constructs, having only the At6669, or the RootP promoter or no additional promoter were used as negative controls.

The binary vectors were introduced to Agrobacterium tumefaciens GV301, or LB4404 competent cells (about 10⁹ cells/mL) by electroporation. The electroporation was performed using a MicroPulser electroporator (Biorad), 0.2 cm cuvettes (Biorad) and EC-2 electroporation program (Biorad). The treated cells were cultured in LB liquid medium at 28° C. for 3 hours, then plated over LB agar supplemented with gentamycin (50 mg/L; for Agrobacterium strains GV301) or streptomycin (300 mg/L; for Agrobacterium strain LB4404) and kanamycin (50 mg/L) at 28° C. for 48 hours. Agrobacterium colonies, which were developed on the selective media, were further analyzed by PCR using the primers designed to span the inserted sequence in the pPI plasmid. The resulting PCR products were isolated and sequenced as described in Example 11 above, to verify that the correct polynucleotide sequences of the invention are properly introduced to the Agrobacterium cells.

Example 13 Transformation of Arabidopsis thaliana Plants with the Polynucleotides of the Invention

Arabidopsis thaliana Columbia plants (T₀ plants) were transformed using the Floral Dip procedure described by Clough and Bent, 1998 (Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J 16:735-43) and by Desfeux et al., 2000 (Female Reproductive Tissues Are the Primary Target of Agrobacterium-Mediated Transformation by the Arabidopsis Floral-Dip Method. Plant Physiol, July 2000, Vol. 123, pp. 895-904), with minor modifications. Briefly, To Plants were sown in 250 ml pots filled with wet peat-based growth mix. The pots are covered with aluminum foil and a plastic dome, kept at 4° C. for 3-4 days, then uncovered and incubated in a growth chamber at 18-24° C. under 16/8 hour light/dark cycles. The T₀ plants were ready for transformation six days before anthesis.

Single colonies of Agrobacterium carrying the binary constructs, were generated as described in Examples 11 and 12 above. Colonies were cultured in LB medium supplemented with kanamycin (50 mg/L) and gentamycin (50 mg/L). The cultures were incubated at 28° C. for 48 hours under vigorous shaking and then centrifuged at 4000 rpm for 5 minutes. The pellets comprising the Agrobacterium cells were re-suspended in a transformation medium containing half-strength (2.15 g/L) Murashige-Skoog (Duchefa); 0.044 μM benzylamino purine (Sigma); 112 μg/L B5 Gambourg vitamins (Sigma); 5% sucrose; and 0.2 ml/L Silwet L-77 (OSI Specialists, CT) in double-distilled water, at pH of 5.7.

Transformation of T₀ plants was performed by inverting each plant into an Agrobacterium suspension, such that the above ground plant tissue was submerged for 3-5 seconds. Each inoculated T₀ plant was immediately placed in a plastic tray, then covered with clear plastic dome to maintain humidity and was kept in the dark at room temperature for 18 hours, to facilitate infection and transformation. Transformed (transgenic) plants were then uncovered and transferred to a greenhouse for recovery and maturation. The transgenic T₀ plants were grown in the greenhouse for 3-5 weeks until siliques are brown and dry. Seeds were harvested from plants and kept at room temperature until sowing.

For generating T₁ and T₂ transgenic plants harboring the genes, seeds collected from transgenic T₀ plants were surface-sterilized by soaking in 70% ethanol for 1 minute, followed by soaking in 5% sodium hypochloride and 0.05% triton for 5 minutes. The surface-sterilized seeds were thoroughly washed in sterile distilled water then placed on culture plates containing half-strength Murashige-Skoog (Duchefa); 2% sucrose; 0.8% plant agar; 50 mM kanamycin; and 200 mM carbenicylin (Duchefa). The culture plates were incubated at 4° C. for 48 hours, then transferred to a growth room at 25° C. for an additional week of incubation. Vital T₁ Arabidopsis plants were transferred to fresh culture plates for another week of incubation. Following incubation the T₁ plants were removed from culture plates and planted in growth mix contained in 250 ml pots. The transgenic plants were allowed to grow in a greenhouse to maturity. Seeds harvested from T₁ plants were cultured and grown to maturity as T₂ plants under the same conditions as used for culturing and growing the T₁ plants.

Example 14 Evaluating Transgenic Arabidopsis NUE Under Low or Normal Nitrogen Conditions Using In Vitro (Tissue Culture) Assays

Assay 1: Plant Growth Under Low and Favorable Nitrogen Concentration Levels

Surface sterilized seeds were sown in basal media [50% Murashige-Skoog medium (MS) supplemented with 0.8% plant agar as solidifying agent] in the presence of Kanamycin (used as a selecting agent). After sowing, plates were transferred for 2-3 days for stratification at 4° C. and then grown at 25° C. under 12-hour light 12-hour dark daily cycles for 7 to 10 days. At this time point, seedlings randomly chosen were carefully transferred to plates containing ½ MS media (15 mM N) for the normal nitrogen concentration treatment and 0.75 mM nitrogen for the low nitrogen concentration treatments. For experiments performed in T₂ lines, each plate contained 5 seedlings of the same transgenic event, and 3-4 different plates (replicates) for each event. For each polynucleotide of the invention at least four-five independent transformation events were analyzed from each construct. For experiments performed in T₁ lines, each plate contained 5 seedlings of 5 independent transgenic events and 3-4 different plates (replicates) were planted. In total, for T₁ lines, 20 independent events were evaluated. Plants expressing the polynucleotides of the invention were compared to the average measurement of the control plants (empty vector or GUS reporter gene under the same promoter) used in the same experiment.

Digital imaging—A laboratory image acquisition system, which consists of a digital reflex camera (Canon EOS 300D) attached with a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which includes 4 light units (4×150 Watts light bulb) and located in a darkroom, is used for capturing images of plantlets sawn in agar plates.

The image capturing process is repeated every 3-4 days starting at day 1 till day 10 (see for example the images in FIGS. 3A-3B). An image analysis system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.39 [Java based image processing program which was developed at the U.S. National Institutes of Health and freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/]. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Seedling analysis—Using the digital analysis seedling data was calculated, including leaf area, root coverage and root length.

The relative growth rate for the various seedling parameters was calculated according to the following formulas XIII, V (described above) and XIV.

Relative growth rate of leaf area=Regression coefficient of leaf area along time course.  Formula XIII:

Relative growth rate of root length=Regression coefficient of root length along time course.  Formula XIV:

At the end of the experiment, plantlets were removed from the media and weighed for the determination of plant fresh weight. Plantlets were then dried for 24 hours at 60° C., and weighed again to measure plant dry weight for later statistical analysis. Growth rate was determined by comparing the leaf area coverage, root coverage and root length, between each couple of sequential photographs, and results are used to resolve the effect of the gene introduced on plant vigor under optimal conditions. Similarly, the effect of the gene introduced on biomass accumulation, under optimal conditions, was determined by comparing the plants' fresh and dry weight to that of control plants (containing an empty vector or the GUS reporter gene under the same promoter). From every construct created, 3-5 independent transformation events are examined in replicates.

Statistical analyses—To identify genes conferring significantly improved plant vigor or enlarged root architecture, the results obtained from the transgenic plants were compared to those obtained from control plants. To identify outperforming genes and constructs, results from the independent transformation events tested were analyzed separately. To evaluate the effect of a gene event over a control the data was analyzed by Student's t-test and the p value is calculated. Results were considered significant if p<0.1. The JMP statistics software package was used (Version 5.2.1, SAS Institute Inc., Cary, N.C., USA).

Experimental Results:

The genes presented in Tables 60-63 showed a significant improvement in plant NUE since they produced larger plant biomass (plant fresh and dry weight and leaf area) in T2 generation (Tables 60-61) or T1 generation (Tables 62-63) when grown under limiting nitrogen growth conditions, compared to control plants. The genes were cloned under the regulation of a constitutive promoter (At6669) or root preferred promoter (RootP). The evaluation of each gene was carried out by testing the performance of different number of events. Some of the genes were evaluated in more than one tissue culture assay. The results obtained in these second experiments were significantly positive as well.

TABLE 60 Genes showing improved plant performance at nitrogen deficient conditions (T2 generation) Plant Biomass Fresh Plant Biomass Dry Weight [gr.] Weight [gr.] Gene p- % Gene p- Name Event # Ave. value incr. Name Event # Ave. Ave. value CONT. — 0.125 — 0.0 CONT. — 0.005 — 0.0 LNU100 14474.3 0.198 0.046 58.5 LNU100 14474.3 0.009 0.023 74.5 LNU100 14473.1 0.145 0.099 15.8 LNU100 14473.1 0.006 0.196 16.7 LNU100 14473.3 0.132 0.728 5.7 LNU104 25033.3 0.007 0.059 40.2 LNU104 25033.3 0.166 0.090 32.5 LNU104 25034.1 0.006 0.310 17.2 LNU104 25034.1 0.130 0.761 3.9 LNU213 24654.4 0.010 0.079 97.5 LNU213 24654.4 0.228 0.068 82.1 LNU213 24653.2 0.009 0.000 77.0 LNU213 24653.2 0.183 0.007 46.2 LNU213 24651.1 0.006 0.454 10.3 LNU213 24651.1 0.134 0.538 7.6 LNU218 24781.7 0.008 0.221 48.0 LNU218 24781.7 0.169 0.355 35.0 LNU218 24783.2 0.007 0.041 44.1 LNU218 24783.2 0.160 0.034 28.3 LNU4 25134.2 0.008 0.017 59.3 LNU4 25134.1 0.186 0.009 49.2 LNU4 25134.1 0.008 0.013 50.0 LNU4 25134.2 0.181 0.051 45.1 LNU48 24802.2 0.010 0.026 104.4 LNU48 24802.2 0.223 0.017 78.4 LNU48 24804.4 0.007 0.014 42.6 LNU48 24803.2 0.151 0.082 20.9 LNU48 24803.2 0.007 0.036 40.2 LNU48 24804.4 0.146 0.090 16.5 LNU8 25063.1 0.011 0.040 118.6 LNU8 25063.1 0.244 0.026 95.6 LNU8 25063.6 0.009 0.175 76.5 LNU8 25063.6 0.182 0.150 45.4 LNU8 25062.2 0.005 0.689 6.9 LNU94 24833.3 0.167 0.027 34.0 LNU94 24833.3 0.008 0.001 47.5 LNU94 24834.1 0.160 0.030 27.7 LNU94 24834.1 0.007 0.008 46.6 LNU94 24834.4 0.133 0.660 6.7 LNU94 24834.4 0.006 0.359 15.7 CONT. — 0.110 — 0.0 CONT. — 0.005 — 0.0 LNU1 24681.3 0.178 0.041 60.9 LNU1 24682.2 0.008 0.015 64.4 LNU1 24682.2 0.155 0.069 40.8 LNU1 24681.3 0.008 0.018 53.7 LNU1 24684.1 0.141 0.037 28.1 LNU1 24681.1 0.007 0.062 29.3 LNU1 24681.1 0.130 0.167 17.9 LNU1 24684.1 0.007 0.036 28.3 LNU1 24682.1 0.120 0.640 8.5 LNU1 24682.1 0.006 0.279 21.5 LNU133 24744.3 0.178 0.005 61.2 LNU133 24741.1 0.009 0.022 79.5 LNU133 24741.1 0.174 0.020 57.2 LNU133 24744.3 0.009 0.001 79.0 LNU133 24741.2 0.117 0.614 5.5 LNU133 24741.2 0.006 0.105 21.5 LNU133 24744.2 0.115 0.651 4.5 LNU133 24744.2 0.006 0.322 11.7 LNU175 24732.4 0.220 0.076 99.3 LNU175 24732.4 0.012 0.054 127.3 LNU175 24732.1 0.191 0.001 72.7 LNU175 24732.1 0.010 0.006 100.0 LNU175 24734.4 0.153 0.155 38.4 LNU175 24734.4 0.008 0.135 52.7 LNU178 14611.5 0.167 0.005 50.8 LNU175 24731.2 0.005 0.566 6.3 LNU178 14614.5 0.141 0.050 27.5 LNU178 14611.5 0.009 0.002 70.7 LNU178 14612.1 0.119 0.527 8.2 LNU178 14614.5 0.007 0.031 38.0 LNU178 14611.1 0.114 0.751 3.3 LNU178 14611.1 0.006 0.448 10.7 LNU215 24664.3 0.174 0.046 57.8 LNU215 24664.3 0.008 0.012 54.1 LNU215 24661.4 0.115 0.781 4.0 LNU215 24661.4 0.006 0.592 9.8 LNU24 24971.2 0.173 0.026 56.6 LNU215 24664.2 0.006 0.567 7.3 LNU24 24973.1 0.164 0.014 48.2 LNU24 24973.1 0.009 0.030 67.8 LNU24 24971.4 0.140 0.317 26.8 LNU24 24971.2 0.008 0.044 63.9 LNU6 24992.3 0.176 0.003 59.8 LNU24 24971.4 0.008 0.193 46.3 LNU6 24994.1 0.137 0.085 24.0 LNU24 24972.1 0.006 0.307 11.2 LNU6 24994.2 0.128 0.208 16.3 LNU6 24992.3 0.009 0.013 67.8 LNU6 24993.3 0.122 0.581 10.2 LNU6 24994.2 0.007 0.040 35.1 LNU6 24994.5 0.118 0.554 6.8 LNU6 24994.1 0.006 0.081 25.4 LNU82 24823.1 0.133 0.171 20.5 LNU6 24993.3 0.006 0.434 12.7 LNU9 25001.3 0.155 0.200 40.5 LNU6 24994.5 0.006 0.322 12.7 LNU9 25001.1 0.138 0.268 25.4 LNU82 24823.1 0.006 0.086 24.4 LNU9 25003.1 0.123 0.419 11.3 LNU9 25001.3 0.007 0.102 33.7 CONT. — 0.104 — 0.0 LNU9 25001.1 0.007 0.162 33.2 LNU120 25463.7 0.172 0.047 66.1 LNU9 25003.1 0.006 0.360 19.0 LNU120 25463.3 0.151 0.018 45.3 CONT. — 0.005 — 0.0 LNU124 14501.7 0.179 0.001 72.5 LNU120 25463.7 0.007 0.230 48.7 LNU124 14502.7 0.120 0.105 15.5 LNU120 25463.3 0.006 0.025 21.5 LNU124 14501.1 0.117 0.229 12.9 LNU124 14501.7 0.007 0.018 41.5 LNU132 14101.9 0.131 0.316 26.1 LNU132 14101.9 0.005 0.616 7.7 LNU132 14102.9 0.126 0.145 21.4 LNU140 14112.7 0.010 0.012 110.3 LNU140 14112.7 0.198 0.000 90.9 LNU180 24724.3 0.012 0.000 148.2 LNU140 14111.6 0.120 0.473 16.0 LNU180 24723.3 0.006 0.044 32.3 LNU140 14114.8 0.118 0.251 13.9 LNU20 24932.4 0.005 0.414 10.8 LNU140 14112.6 0.114 0.467 9.9 LNU36 25562.3 0.009 0.130 82.6 LNU180 24724.3 0.272 0.000 162.1 LNU71 25853.4 0.007 0.043 53.3 LNU180 24723.3 0.201 0.010 93.9 CONT. — 0.005 — 0.0 LNU180 24722.2 0.110 0.700 6.2 LNU1 24681.3 0.007 0.295 45.1 LNU196 25534.1 0.138 0.168 32.7 LNU1 24683.2 0.005 0.703 4.9 LNU196 25533.1 0.119 0.207 15.0 LNU110 24952.2 0.015 0.450 215.1 LNU20 24932.4 0.149 0.119 43.4 LNU110 24952.3 0.008 0.159 60.0 LNU20 24933.2 0.112 0.591 7.4 LNU110 24953.3 0.006 0.466 18.6 LNU36 25562.3 0.193 0.138 85.9 LNU110 24953.2 0.005 0.276 13.3 LNU36 25562.4 0.115 0.538 10.9 LNU175 24732.2 0.008 0.127 66.8 LNU71 25853.4 0.187 0.035 79.9 LNU175 24733.4 0.005 0.748 5.9 LNU71 25852.4 0.117 0.413 13.2 LNU19 25151.1 0.006 0.094 25.0 CONT. — 0.117 — 0.0 LNU19 25153.3 0.006 0.456 24.5 LNU1 24681.3 0.156 0.381 32.5 LNU215 24664.2 0.008 0.001 70.0 LNU1 24683.2 0.133 0.365 13.5 LNU215 24663.3 0.005 0.272 12.8 LNU110 24953.3 0.164 0.014 40.1 LNU215 24663.4 0.005 0.339 10.7 LNU110 24952.3 0.164 0.248 39.7 LNU27 24873.4 0.007 0.097 46.7 LNU110 24953.2 0.130 0.389 11.1 LNU27 24873.1 0.007 0.161 45.7 LNU175 24732.2 0.182 0.105 55.4 LNU27 24872.4 0.005 0.541 6.5 LNU175 24733.4 0.139 0.069 18.7 LNU44 24924.2 0.019 0.270 304.1 LNU175 24734.4 0.128 0.430 9.5 LNU44 24924.3 0.009 0.055 100.2 LNU19 25151.1 0.186 0.081 58.6 LNU44 24922.3 0.005 0.770 8.1 LNU19 25153.3 0.155 0.241 32.5 LNU44 24923.3 0.005 0.576 5.4 LNU19 25151.11 0.129 0.581 10.0 LNU54 24903.5 0.012 0.004 154.8 LNU215 24664.2 0.196 0.020 67.1 LNU54 24903.3 0.008 0.014 79.0 LNU215 24663.4 0.147 0.139 25.4 LNU54 24901.2 0.008 0.049 75.3 LNU215 24663.3 0.128 0.466 8.9 LNU79 24884.4 0.011 0.028 122.5 LNU215 24661.4 0.127 0.595 8.4 LNU79 24884.3 0.008 0.050 72.1 LNU27 24873.1 0.205 0.097 74.4 LNU79 24881.1 0.007 0.041 47.8 LNU27 24873.4 0.172 0.044 46.2 LNU79 24882.2 0.005 0.321 13.3 LNU27 24872.4 0.130 0.200 10.6 CONT. — 0.006 — 0.0 LNU44 24924.3 0.239 0.019 103.9 LNU109 24891.5 0.009 0.009 52.1 LNU44 24924.2 0.218 0.056 85.8 LNU109 24892.5 0.008 0.184 38.3 LNU44 24922.3 0.151 0.203 28.6 LNU109 24892.6 0.008 0.164 29.3 LNU44 24923.3 0.123 0.759 4.5 LNU109 24891.2 0.007 0.371 28.0 LNU54 24903.5 0.259 0.000 121.0 LNU110 24952.1 0.015 0.000 162.5 LNU54 24901.2 0.201 0.005 70.9 LNU110 24953.2 0.010 0.036 79.1 LNU54 24903.3 0.166 0.071 41.4 LNU110 24952.3 0.009 0.153 51.6 LNU79 24884.4 0.247 0.003 110.9 LNU110 24954.3 0.007 0.063 27.1 LNU79 24884.3 0.190 0.031 61.6 LNU133 24744.3 0.011 0.020 90.7 LNU79 24881.1 0.169 0.074 44.2 LNU133 24741.1 0.010 0.091 63.2 LNU79 24882.2 0.135 0.113 14.9 LNU133 24741.2 0.008 0.006 37.5 CONT. — 0.138 — 0.0 LNU133 24744.2 0.007 0.220 21.1 LNU109 24892.5 0.200 0.181 44.6 LNU133 24742.2 0.006 0.581 5.7 LNU109 24891.5 0.179 0.056 29.3 LNU19 25151.1 0.011 0.124 86.9 LNU109 24891.2 0.179 0.351 29.1 LNU27 24873.4 0.012 0.015 107.9 LNU109 24892.6 0.160 0.417 15.9 LNU44 24922.3 0.014 0.009 136.3 LNU110 24952.1 0.333 0.006 140.4 LNU44 24923.1 0.007 0.129 25.0 LNU110 24953.2 0.224 0.053 61.9 LNU44 24924.3 0.007 0.191 21.6 LNU110 24952.3 0.189 0.257 36.4 LNU54 24901.2 0.009 0.041 59.4 LNU133 24744.3 0.213 0.014 54.0 LNU54 24903.5 0.009 0.036 58.5 LNU133 24741.1 0.176 0.226 27.1 LNU54 24902.4 0.009 0.037 52.9 LNU133 24741.2 0.175 0.056 26.5 LNU6 24994.5 0.009 0.047 55.1 LNU133 24744.2 0.150 0.549 8.5 LNU6 24992.3 0.009 0.018 54.6 LNU19 25151.1 0.198 0.151 42.8 LNU6 24994.1 0.007 0.450 22.0 LNU27 24873.4 0.235 0.021 70.0 LNU6 24994.2 0.007 0.201 14.3 LNU44 24922.3 0.259 0.004 86.9 LNU79 24884.4 0.010 0.008 79.1 LNU44 24923.1 0.162 0.055 17.1 LNU79 24882.2 0.010 0.005 64.5 LNU44 24924.3 0.156 0.511 12.6 LNU79 24881.1 0.008 0.049 45.2 LNU54 24901.2 0.215 0.060 55.2 LNU79 24884.3 0.007 0.204 21.6 LNU54 24903.5 0.188 0.013 36.2 CONT. — 0.004 — 0.0 LNU54 24902.4 0.187 0.003 35.2 LNU109 24892.8 0.009 0.040 152.1 LNU6 24992.3 0.177 0.118 27.9 LNU109 24891.2 0.009 0.005 140.4 LNU6 24994.5 0.174 0.084 25.8 LNU109 24892.5 0.005 0.058 48.6 LNU6 24994.1 0.165 0.300 19.0 LNU109 24891.5 0.005 0.205 35.6 LNU6 24994.2 0.144 0.779 4.4 LNU143 25971.5 0.006 0.039 65.1 LNU79 24884.4 0.218 0.020 57.8 LNU143 25975.3 0.006 0.183 58.9 LNU79 24882.2 0.206 0.105 48.6 LNU143 25972.1 0.005 0.046 47.9 LNU79 24881.1 0.169 0.118 21.8 LNU143 25975.2 0.005 0.118 41.1 CONT. — 0.113 — 0.0 LNU143 25971.2 0.004 0.699 6.8 LNU109 24892.8 0.192 0.149 69.7 LNU154 14601.6 0.007 0.067 104.1 LNU109 24891.2 0.178 0.028 57.7 LNU154 14604.7 0.007 0.095 102.7 LNU109 24892.5 0.139 0.350 23.4 LNU154 14604.6 0.007 0.101 80.8 LNU109 24891.5 0.121 0.763 6.9 LNU154 14602.8 0.006 0.092 52.1 LNU143 25972.1 0.143 0.231 26.2 LNU154 14604.4 0.005 0.233 36.3 LNU143 25975.3 0.132 0.524 16.8 LNU196 25532.2 0.010 0.019 164.4 LNU143 25971.5 0.124 0.536 9.9 LNU196 25534.1 0.007 0.075 93.2 LNU154 14604.7 0.167 0.182 47.9 LNU196 25531.2 0.006 0.150 54.8 LNU154 14604.6 0.164 0.116 45.2 LNU196 25532.1 0.005 0.350 38.4 LNU154 14601.6 0.154 0.353 36.3 LNU207 24642.5 0.008 0.086 119.2 LNU196 25532.2 0.220 0.017 94.9 LNU207 24642.4 0.008 0.029 115.1 LNU196 25534.1 0.172 0.103 52.6 LNU207 24644.18 0.007 0.040 78.8 LNU196 25531.2 0.140 0.382 24.3 LNU207 24641.1 0.004 0.564 11.0 LNU196 25532.1 0.121 0.716 7.6 LNU288 14562.12 0.005 0.045 49.3 LNU207 24642.5 0.177 0.042 56.6 LNU288 14562.7 0.005 0.181 45.2 LNU207 24642.4 0.166 0.022 47.3 LNU288 14562.9 0.005 0.292 36.3 LNU207 24644.18 0.152 0.058 34.8 LNU288 14562.1 0.004 0.408 21.9 LNU288 14562.9 0.120 0.720 5.8 LNU288 14564.9 0.004 0.427 17.1 LNU50 26024.2 0.153 0.131 35.4 LNU50 26024.2 0.006 0.085 58.9 LNU52 25723.2 0.242 0.001 114.0 LNU50 26025.4 0.005 0.080 39.0 LNU52 25721.4 0.172 0.302 52.1 LNU50 26023.2 0.005 0.207 37.0 LNU52 25721.3 0.125 0.624 10.3 LNU50 26022.1 0.004 0.464 19.9 CONT. — 0.125 — 0.0 LNU50 26023.5 0.004 0.507 13.0 LNU143 25975.2 0.132 0.701 6.0 LNU52 25723.2 0.012 0.001 230.8 LNU154 14602.8 0.152 0.202 21.6 LNU52 25721.4 0.009 0.172 134.2 LNU154 14604.4 0.140 0.688 12.4 LNU52 25721.3 0.006 0.062 54.8 LNU154 14601.6 0.133 0.706 6.7 LNU52 25721.1 0.005 0.481 32.2 LNU207 24642.5 0.227 0.038 81.8 CONT. — 0.006 — 0.0 LNU207 24641.1 0.197 0.068 58.0 LNU143 25975.3 0.006 0.736 5.7 LNU207 24642.4 0.155 0.239 24.6 LNU154 14602.8 0.008 0.061 36.7 LNU211 24771.1 0.143 0.348 14.4 LNU154 14601.6 0.006 0.592 10.2 LNU211 24774.4 0.135 0.764 7.9 LNU207 24642.5 0.011 0.028 91.5 LNU52 25723.2 0.202 0.194 61.8 LNU207 24641.1 0.008 0.094 51.5 LNU52 25721.2 0.191 0.018 52.8 LNU207 24642.4 0.007 0.244 28.1 LNU52 25723.1 0.183 0.022 46.8 LNU211 24771.1 0.009 0.007 60.5 LNU52 25721.1 0.170 0.140 36.2 LNU211 24774.4 0.007 0.411 18.7 LNU69 14572.8 0.192 0.089 54.2 LNU52 25721.2 0.009 0.029 59.2 LNU69 14571.1 0.164 0.335 31.7 LNU52 25721.1 0.009 0.065 56.0 LNU69 14572.9 0.131 0.794 5.2 LNU52 25723.2 0.008 0.176 48.4 CONT. — 0.123 — 0.0 LNU52 25723.1 0.007 0.241 23.7 LNU150 24842.9 0.199 0.000 61.6 LNU69 14571.1 0.008 0.095 48.4 LNU150 24841.9 0.168 0.204 36.0 LNU69 14572.8 0.006 0.278 14.7 LNU150 24843.5 0.152 0.280 23.5 LNU69 14572.9 0.006 0.482 12.0 LNU179 24632.5 0.185 0.008 49.8 CONT. — 0.006 — 0.0 LNU179 24631.9 0.146 0.079 18.6 LNU150 24842.9 0.009 0.000 60.6 LNU232 26003.7 0.148 0.137 20.4 LNU150 24841.9 0.007 0.462 19.7 LNU235 26185.3 0.182 0.161 47.4 LNU179 24632.5 0.008 0.139 42.3 LNU235 26184.4 0.173 0.171 40.6 LNU235 26184.4 0.008 0.111 43.6 LNU242 25473.1 0.184 0.064 48.9 LNU235 26185.3 0.007 0.425 21.4 LNU242 25474.1 0.158 0.012 28.1 LNU242 25473.1 0.007 0.047 23.5 LNU242 25471.1 0.151 0.138 22.4 LNU242 25474.1 0.007 0.335 11.2 LNU76 26423.1 0.181 0.032 46.5 LNU242 25471.1 0.006 0.525 8.2 LNU76 26421.2 0.163 0.150 31.9 LNU76 26423.1 0.008 0.048 38.0 LNU76 26425.1 0.148 0.327 20.1 LNU76 26421.2 0.007 0.155 23.5 LNU76 26421.1 0.145 0.294 18.0 LNU76 26425.1 0.007 0.569 12.9 LNU76 26422.2 0.136 0.415 10.4 LNU76 26421.1 0.006 0.730 5.6 LNU95 13985.11 0.211 0.001 71.2 LNU95 13985.11 0.011 0.001 84.9 LNU95 13985.15 0.145 0.495 17.6 LNU95 13985.12 0.007 0.535 13.3 LNU95 13985.12 0.144 0.439 16.7 LNU95 13985.15 0.007 0.716 11.6 CONT. — 0.128 — 0.0 CONT. — 0.006 — 0.0 LNU118 14013.8 0.187 0.095 46.0 LNU118 14013.6 0.010 0.019 70.3 LNU118 14013.6 0.182 0.009 41.9 LNU118 14012.15 0.008 0.122 41.6 LNU118 14012.15 0.166 0.282 29.8 LNU118 14013.8 0.008 0.070 38.2 LNU150 24841.9 0.163 0.240 27.0 LNU118 14012.12 0.007 0.604 12.1 LNU150 24842.9 0.136 0.793 6.2 LNU150 24841.6 0.007 0.213 19.8 LNU150 24841.6 0.135 0.634 5.2 LNU150 24841.9 0.007 0.506 13.4 LNU179 24631.7 0.161 0.036 25.9 LNU179 24631.7 0.008 0.031 36.0 LNU179 24631.6 0.148 0.451 15.4 LNU179 24631.6 0.007 0.225 19.4 LNU179 24631.9 0.137 0.728 7.2 LNU232 26001.5 0.008 0.191 41.6 LNU232 26001.5 0.161 0.388 25.6 LNU232 26003.6 0.006 0.660 8.7 LNU235 26185.2 0.241 0.023 88.2 LNU235 26184.4 0.013 0.002 115.2 LNU235 26184.4 0.237 0.006 85.1 LNU235 26185.2 0.012 0.020 99.8 LNU235 26184.2 0.211 0.044 64.6 LNU235 26184.2 0.010 0.019 72.4 LNU235 26182.1 0.147 0.303 14.3 LNU242 25474.1 0.007 0.042 26.6 LNU242 25474.1 0.148 0.306 15.6 LNU288 14563.9 0.011 0.003 83.1 LNU288 14563.9 0.232 0.000 81.1 LNU288 14562.1 0.010 0.004 65.6 LNU288 14562.1 0.208 0.025 62.0 LNU288 14564.9 0.007 0.114 23.6 LNU288 14564.9 0.169 0.117 31.9 LNU288 14562.7 0.007 0.420 15.9 LNU288 14562.7 0.166 0.237 29.2 LNU76 26421.2 0.009 0.307 56.1 LNU76 26421.2 0.193 0.330 50.5 LNU76 26423.1 0.008 0.313 41.6 LNU76 26423.1 0.176 0.314 37.7 LNU76 26422.2 0.007 0.489 18.1 LNU76 26422.2 0.151 0.434 18.1 LNU95 13985.16 0.014 0.005 133.6 LNU95 13985.16 0.250 0.003 94.8 LNU95 13985.12 0.011 0.000 92.9 LNU95 13985.12 0.239 0.001 86.4 LNU95 13985.15 0.011 0.020 86.1 LNU95 13985.15 0.223 0.008 74.1 LNU95 13985.19 0.007 0.490 11.7 LNU95 13985.19 0.136 0.658 6.5 CONT. — 0.007 — 0.0 CONT. — 0.149 — 0.0 LNU101 27632.7 0.007 0.435 9.2 LNU101 27632.7 0.179 0.122 19.6 LNU101 27632.1 0.007 0.685 5.9 LNU128 26515.3 0.210 0.062 40.6 LNU101 27635.1 0.007 0.516 4.4 LNU192 28315.2 0.200 0.012 33.7 LNU128 26515.3 0.010 0.081 45.4 LNU206 27621.2 0.180 0.159 20.7 LNU192 28315.2 0.009 0.015 33.5 LNU211 24771.1 0.208 0.018 39.5 LNU192 28313.3 0.007 0.598 4.4 LNU211 24773.2 0.162 0.576 8.8 LNU206 27621.2 0.008 0.001 23.8 LNU282 27563.3 0.204 0.036 36.4 LNU211 24771.1 0.011 0.059 66.6 LNU282 27562.1 0.164 0.466 9.7 LNU211 24773.2 0.008 0.451 22.3 LNU69 14571.1 0.208 0.022 39.5 LNU211 24773.1 0.007 0.509 5.9 LNU75 27572.1 0.163 0.669 8.9 LNU282 27563.3 0.010 0.018 54.7 LNU75 27572.2 0.153 0.779 2.3 LNU282 27563.1 0.008 0.141 17.1 CONT. — 0.121 — 0.0 LNU282 27562.1 0.007 0.571 7.7 LNU101 27632.5 0.151 0.151 25.2 LNU69 14571.1 0.011 0.000 58.1 LNU118 14013.6 0.194 0.050 60.0 LNU69 14572.9 0.007 0.722 6.2 LNU118 14013.9 0.155 0.605 28.5 LNU75 27572.2 0.008 0.191 18.5 LNU118 14012.15 0.153 0.053 26.6 LNU75 27572.1 0.007 0.647 7.4 LNU118 14012.12 0.128 0.683 5.7 CONT. — 0.005 — 0.0 LNU206 27621.1 0.208 0.003 72.3 LNU101 27632.5 0.006 0.003 36.7 LNU206 27622.1 0.208 0.033 72.2 LNU118 14013.6 0.007 0.027 59.8 LNU206 27621.2 0.207 0.062 71.3 LNU118 14012.15 0.007 0.008 50.7 LNU206 27622.4 0.162 0.285 34.0 LNU118 14013.8 0.005 0.693 9.9 LNU249 26153.1 0.209 0.002 73.0 LNU118 14013.9 0.005 0.674 6.2 LNU249 26154.2 0.168 0.104 39.1 LNU206 27621.1 0.010 0.003 112.9 LNU282 27563.1 0.205 0.000 69.2 LNU206 27622.1 0.010 0.056 110.7 LNU282 27565.2 0.172 0.081 42.2 LNU206 27621.2 0.010 0.073 109.1 LNU282 27565.1 0.136 0.457 12.7 LNU206 27622.4 0.007 0.230 57.6 LNU288 14564.8 0.255 0.004 110.8 LNU249 26153.1 0.010 0.010 114.5 LNU288 14563.9 0.252 0.001 108.8 LNU249 26154.2 0.008 0.229 65.7 LNU288 14562.9 0.180 0.001 48.7 LNU249 26152.4 0.005 0.454 11.5 LNU288 14563.6 0.156 0.052 29.3 LNU249 26152.2 0.005 0.664 6.7 LNU288 14562.7 0.127 0.720 5.0 LNU282 27563.1 0.008 0.006 78.0 LNU75 27572.3 0.278 0.010 130.0 LNU282 27565.2 0.007 0.125 53.9 LNU75 27572.2 0.250 0.054 107.0 LNU282 27565.1 0.005 0.749 5.6 LNU75 27571.4 0.245 0.014 102.6 LNU288 14563.9 0.011 0.005 144.5 LNU75 27571.2 0.227 0.000 88.0 LNU288 14564.8 0.010 0.009 120.4 CONT. — 0.144 — 0.0 LNU288 14562.9 0.007 0.048 58.7 LNU11 28204.3 0.154 0.501 7.1 LNU288 14563.6 0.007 0.085 52.8 LNU183 24863.1 0.152 0.610 5.5 LNU288 14562.7 0.006 0.116 24.9 LNU201 28222.2 0.161 0.452 11.8 LNU75 27572.2 0.014 0.054 192.2 LNU268 26045.1 0.163 0.186 13.5 LNU75 27572.3 0.012 0.011 153.1 CONT. — 0.137 — 0.0 LNU75 27571.2 0.010 0.002 117.2 LNU11 28205.1 0.201 0.011 46.8 LNU75 27571.4 0.010 0.003 109.7 LNU11 28203.2 0.180 0.062 31.3 CONT. — 0.006 — 0.0 LNU11 28204.1 0.150 0.569 9.5 LNU11 28204.3 0.007 0.121 26.6 LNU11 28202.5 0.150 0.669 9.5 LNU11 28205.2 0.006 0.737 7.7 LNU11 28205.2 0.143 0.634 4.5 LNU14 27823.2 0.006 0.686 2.1 LNU112 28212.1 0.178 0.123 29.8 LNU183 24863.1 0.006 0.752 4.3 LNU112 28212.4 0.156 0.058 14.2 LNU201 28222.2 0.006 0.679 9.4 LNU112 28212.3 0.155 0.158 12.9 LNU201 28223.1 0.006 0.773 3.0 LNU14 27821.4 0.179 0.108 30.8 LNU268 26044.2 0.007 0.291 21.0 LNU14 27821.3 0.177 0.103 29.4 LNU268 26045.1 0.007 0.087 18.0 LNU14 27824.2 0.162 0.113 18.6 CONT. — 0.006 — 0.0 LNU183 24864.6 0.205 0.005 49.5 LNU11 28205.1 0.008 0.211 27.7 LNU183 24863.1 0.203 0.097 48.0 LNU11 28204.1 0.007 0.466 13.3 LNU183 24863.12 0.195 0.001 42.5 LNU11 28203.2 0.007 0.514 9.6 LNU183 24865.1 0.182 0.012 33.1 LNU11 28202.5 0.007 0.747 8.8 LNU191 28325.4 0.182 0.127 32.8 LNU112 28212.1 0.009 0.100 38.2 LNU191 28323.1 0.177 0.021 29.0 LNU112 28212.3 0.007 0.185 16.5 LNU191 28324.2 0.167 0.070 21.7 LNU112 28212.4 0.007 0.598 6.0 LNU191 28321.3 0.157 0.137 14.5 LNU14 27821.4 0.008 0.083 28.9 LNU201 28222.2 0.230 0.047 68.1 LNU14 27821.3 0.008 0.212 22.1 LNU201 28221.3 0.163 0.247 19.2 LNU14 27824.2 0.007 0.268 13.3 LNU201 28223.3 0.162 0.280 18.1 LNU183 24863.12 0.009 0.005 51.4 LNU268 26041.4 0.190 0.160 39.0 LNU183 24864.6 0.009 0.030 49.8 LNU268 26043.4 0.156 0.297 13.7 LNU183 24863.1 0.009 0.013 42.6 CONT. — 0.126 — 0.0 LNU183 24865.1 0.009 0.029 42.6 LNU107 14584.9 0.221 0.167 74.4 LNU191 28325.4 0.009 0.063 37.8 LNU107 14583.8 0.175 0.117 38.3 LNU191 28323.1 0.008 0.017 30.5 LNU107 14585.5 0.137 0.598 8.5 LNU191 28324.2 0.007 0.554 7.2 LNU116 14492.5 0.201 0.237 58.9 LNU191 28321.3 0.007 0.689 5.2 LNU116 14494.5 0.188 0.192 48.8 LNU201 28222.2 0.012 0.014 86.3 LNU116 14492.9 0.178 0.105 40.7 LNU201 28221.3 0.009 0.158 38.6 LNU116 14493.6 0.160 0.439 26.3 LNU201 28223.3 0.007 0.290 20.1 LNU121 25642.2 0.233 0.043 83.8 LNU268 26041.4 0.009 0.138 44.2 LNU121 27713.4 0.190 0.006 50.0 LNU268 26043.4 0.007 0.746 5.2 LNU121 27711.1 0.188 0.010 48.7 CONT. — 0.005 — 0.0 LNU121 27713.1 0.164 0.155 29.3 LNU107 14583.8 0.009 0.034 86.2 LNU126 25343.1 0.199 0.011 57.4 LNU107 14584.9 0.008 0.021 73.0 LNU126 25345.1 0.175 0.153 38.4 LNU107 14585.5 0.006 0.282 24.3 LNU126 25343.3 0.172 0.095 36.3 LNU116 14492.9 0.008 0.017 66.1 LNU158 27433.3 0.201 0.015 58.6 LNU116 14492.5 0.007 0.048 54.5 LNU158 27433.2 0.187 0.075 47.6 LNU116 14494.5 0.007 0.101 43.9 LNU158 27432.5 0.156 0.399 23.5 LNU116 14493.6 0.005 0.544 7.9 LNU177 24762.6 0.214 0.018 69.3 LNU121 25642.2 0.010 0.017 106.3 LNU182 25384.1 0.219 0.001 73.0 LNU121 27713.4 0.009 0.001 83.1 LNU182 25384.2 0.170 0.154 34.3 LNU121 27713.1 0.007 0.010 48.1 LNU182 25384.5 0.152 0.450 20.3 LNU121 27711.1 0.007 0.010 47.6 LNU182 27521.4 0.139 0.537 10.2 LNU126 25343.1 0.009 0.022 97.4 LNU2 25713.1 0.186 0.107 47.2 LNU126 25345.1 0.008 0.145 59.3 LNU2 27842.3 0.157 0.298 23.9 LNU126 25343.3 0.007 0.085 39.7 LNU2 27842.1 0.134 0.697 6.0 LNU158 27433.3 0.010 0.015 107.4 LNU225 25991.5 0.212 0.003 67.5 LNU158 27432.5 0.008 0.100 69.3 LNU225 25991.2 0.190 0.157 49.9 LNU158 27433.2 0.008 0.092 59.8 LNU239 26284.1 0.156 0.273 23.1 LNU177 24762.6 0.008 0.001 77.8 LNU239 26283.2 0.138 0.528 9.0 LNU177 24764.9 0.006 0.184 32.3 LNU83 27681.4 0.161 0.237 27.5 LNU177 24765.2 0.006 0.282 21.2 LNU83 27684.1 0.157 0.208 24.0 LNU182 25384.1 0.010 0.000 107.4 LNU83 27685.1 0.138 0.522 9.1 LNU182 25384.2 0.008 0.006 77.2 CONT. — 0.118 — 0.0 LNU182 27521.4 0.007 0.006 39.2 LNU107 14584.9 0.230 0.000 95.3 LNU182 25384.5 0.006 0.172 30.7 LNU107 14585.2 0.178 0.001 50.9 LNU2 25713.1 0.008 0.060 74.1 LNU107 14583.8 0.161 0.043 36.1 LNU2 27842.3 0.007 0.037 43.9 LNU107 14585.5 0.128 0.604 8.2 LNU2 27842.1 0.006 0.035 27.5 LNU116 14492.5 0.235 0.000 98.7 LNU225 25991.5 0.011 0.000 136.0 LNU116 14493.6 0.211 0.001 78.9 LNU225 25991.2 0.010 0.186 115.3 LNU116 14494.5 0.186 0.118 57.7 LNU239 26284.1 0.007 0.012 40.7 LNU116 14492.9 0.157 0.046 33.4 LNU239 26283.2 0.005 0.576 9.5 LNU116 14491.5 0.146 0.044 23.7 LNU239 26281.1 0.005 0.686 9.0 LNU121 27711.1 0.220 0.007 86.6 LNU57 27854.5 0.005 0.373 13.2 LNU121 27713.4 0.218 0.004 84.4 LNU83 27684.1 0.007 0.162 47.1 LNU121 25642.2 0.215 0.002 81.9 LNU83 27681.4 0.007 0.169 41.1 LNU121 27713.1 0.209 0.000 76.9 CONT. — 0.004 — 0.0 LNU121 27713.3 0.136 0.357 15.2 LNU107 14584.9 0.010 0.002 148.1 LNU126 25343.1 0.181 0.029 53.3 LNU107 14585.2 0.007 0.021 84.0 LNU126 25341.1 0.153 0.415 29.7 LNU107 14583.8 0.007 0.055 70.4 LNU126 25343.3 0.133 0.604 12.4 LNU107 14585.5 0.005 0.107 24.7 LNU126 25345.1 0.125 0.730 6.0 LNU116 14492.5 0.010 0.000 140.7 LNU158 27433.3 0.260 0.000 120.3 LNU116 14494.5 0.008 0.000 109.3 LNU158 27432.5 0.219 0.011 85.5 LNU116 14493.6 0.008 0.000 104.9 LNU158 27433.2 0.200 0.106 69.9 LNU116 14492.9 0.007 0.131 74.7 LNU158 27434.1 0.140 0.454 18.3 LNU116 14491.5 0.006 0.000 58.6 LNU177 24764.12 0.227 0.027 92.6 LNU121 25642.2 0.009 0.022 122.8 LNU177 24763.6 0.161 0.172 36.3 LNU121 27713.1 0.008 0.022 105.6 LNU177 24764.9 0.154 0.225 30.4 LNU121 27711.1 0.008 0.051 104.9 LNU182 25384.1 0.175 0.039 48.6 LNU121 27713.4 0.008 0.006 95.1 LNU182 25384.6 0.173 0.038 47.0 LNU121 27713.3 0.006 0.228 47.5 LNU182 25384.5 0.135 0.513 14.4 LNU126 25343.1 0.007 0.010 77.2 LNU2 27842.1 0.210 0.001 78.2 LNU126 25343.3 0.005 0.246 27.2 LNU2 27842.3 0.175 0.043 48.6 LNU126 25341.1 0.005 0.314 25.3 LNU2 25713.1 0.132 0.702 11.5 LNU126 25343.4 0.005 0.257 17.9 LNU2 27845.2 0.127 0.715 7.9 LNU126 25345.1 0.004 0.624 4.9 LNU225 25991.3 0.282 0.013 138.6 LNU158 27433.3 0.011 0.001 180.9 LNU225 25991.2 0.223 0.003 89.0 LNU158 27433.2 0.010 0.082 138.3 LNU225 25991.8 0.189 0.000 60.3 LNU158 27432.5 0.010 0.012 137.0 LNU225 25991.1 0.159 0.143 34.7 LNU177 24764.12 0.010 0.012 147.5 LNU239 26281.1 0.152 0.239 28.9 LNU177 24763.6 0.007 0.049 67.3 LNU239 26284.2 0.149 0.094 26.5 LNU177 24762.6 0.005 0.249 17.3 LNU239 26284.1 0.136 0.439 14.9 LNU177 24765.2 0.005 0.333 16.0 LNU239 26283.2 0.130 0.353 9.8 LNU182 25384.1 0.008 0.006 93.8 LNU57 27852.1 0.198 0.010 68.0 LNU182 25384.6 0.007 0.019 74.1 LNU57 27851.2 0.192 0.061 62.3 LNU182 25384.5 0.005 0.160 26.5 LNU57 27854.5 0.143 0.077 21.2 LNU182 25384.2 0.005 0.450 16.0 LNU57 27854.3 0.140 0.256 18.5 LNU2 27842.1 0.009 0.027 131.5 LNU83 27685.1 0.288 0.001 143.9 LNU2 27842.3 0.007 0.104 66.7 LNU83 27685.2 0.201 0.003 70.6 LNU2 25713.1 0.007 0.362 63.0 LNU83 27681.4 0.164 0.041 38.7 LNU2 27845.2 0.006 0.161 52.5 CONT. — 0.127 — 0.0 LNU2 27845.3 0.005 0.028 30.2 LNU17 13991.1 0.145 0.39  14.5 LNU225 25991.2 0.011 0.007 161.1 LNU17 13993.9 0.135 0.71  6.1 LNU225 25991.3 0.010 0.051 139.5 LNU225 25991.8 0.007 0.001 64.2 LNU225 25991.1 0.005 0.067 31.5 LNU239 26284.2 0.007 0.054 63.6 LNU239 26281.1 0.006 0.190 54.9 LNU239 26283.2 0.006 0.043 41.4 LNU239 26284.1 0.005 0.414 14.8 LNU57 27852.1 0.009 0.000 133.3 LNU57 27851.2 0.009 0.006 110.5 LNU57 27854.5 0.006 0.046 41.4 LNU57 27854.3 0.005 0.404 19.8 LNU83 27685.1 0.010 0.000 156.2 LNU83 27685.2 0.009 0.000 111.7 LNU83 27681.4 0.007 0.018 80.9 LNU83 27682.1 0.004 0.479 6.8 Table 60. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

TABLE 61 Genes showing improved plant performance at nitrogen deficient conditions (T2 generation) Leaf Area [cm2] Gene Name Event # Average p-value % increment CONTROL — 0.559 — 0.0 LNU100 14474.3 0.877 0.032 56.8 LNU100 14473.1 0.646 0.097 15.5 LNU104 25033.3 0.794 0.005 41.9 LNU104 25034.1 0.742 0.047 32.6 LNU104 25032.2 0.581 0.749 3.8 LNU213 24654.4 1.040 0.036 86.0 LNU213 24653.2 0.896 0.000 60.1 LNU213 24651.1 0.607 0.343 8.5 LNU218 24781.7 0.777 0.116 38.8 LNU218 24783.2 0.775 0.086 38.5 LNU4 25134.2 0.858 0.002 53.4 LNU4 25134.1 0.703 0.183 25.6 LNU48 24802.2 0.897 0.009 60.3 LNU48 24803.2 0.757 0.005 35.3 LNU48 24804.4 0.726 0.066 29.8 LNU8 25063.1 0.974 0.002 74.0 LNU8 25063.6 0.863 0.111 54.3 LNU8 25062.2 0.593 0.706 5.9 LNU94 24833.3 0.761 0.034 36.0 LNU94 24834.4 0.692 0.208 23.7 LNU94 24834.1 0.680 0.234 21.6 CONTROL — 0.765 — 0.0 LNU1 24681.3 0.979 0.168 28.0 LNU1 24684.1 0.918 0.237 20.1 LNU1 24682.1 0.916 0.285 19.8 LNU1 24682.2 0.879 0.477 14.9 LNU1 24681.1 0.848 0.515 10.9 LNU1 24683.2 0.822 0.641 7.5 LNU133 24744.3 1.103 0.062 44.3 LNU133 24741.1 1.024 0.081 33.8 LNU133 24744.2 0.822 0.651 7.5 LNU175 24732.4 1.207 0.033 57.8 LNU175 24732.1 1.192 0.019 55.9 LNU175 24734.4 0.938 0.207 22.7 LNU178 14614.5 1.132 0.047 48.0 LNU178 14611.5 0.986 0.123 28.9 LNU178 14612.1 0.832 0.567 8.8 LNU178 14611.1 0.809 0.729 5.8 LNU215 24664.3 1.083 0.061 41.6 LNU215 24661.4 0.820 0.659 7.2 LNU24 24973.1 1.022 0.103 33.7 LNU24 24971.2 0.985 0.119 28.8 LNU24 24971.4 0.971 0.301 27.0 LNU6 24992.3 1.049 0.063 37.2 LNU6 24994.1 0.885 0.347 15.8 LNU6 24993.3 0.855 0.506 11.8 LNU6 24994.2 0.815 0.696 6.6 LNU82 24823.1 0.911 0.252 19.1 LNU9 25001.3 0.892 0.361 16.7 LNU9 25003.1 0.879 0.416 14.9 LNU9 25001.1 0.829 0.663 8.4 CONTROL — 0.561 — 0.0 LNU120 25463.7 0.758 0.001 35.0 LNU120 25463.3 0.749 0.003 33.4 LNU124 14501.7 0.767 0.019 36.6 LNU124 14501.1 0.666 0.072 18.6 LNU124 14502.7 0.645 0.018 14.9 LNU132 14102.7 0.622 0.288 10.9 LNU132 14102.9 0.622 0.258 10.8 LNU140 14112.7 0.953 0.000 69.8 LNU140 14111.6 0.686 0.046 22.2 LNU140 14112.6 0.593 0.465 5.6 LNU140 14114.8 0.582 0.553 3.7 LNU180 24724.3 0.975 0.003 73.6 LNU180 24723.3 0.774 0.044 37.8 LNU196 25534.1 0.674 0.165 20.0 LNU196 25533.1 0.631 0.476 12.4 LNU20 24932.4 0.644 0.190 14.6 LNU20 24933.2 0.640 0.421 14.0 LNU36 25562.3 0.860 0.107 53.1 LNU36 25562.4 0.574 0.750 2.2 LNU71 25853.4 0.835 0.005 48.8 CONTROL — 0.597 — 0.0 LNU1 24681.3 0.695 0.438 16.4 LNU110 24952.3 0.872 0.056 46.1 LNU110 24953.3 0.789 0.110 32.1 LNU110 24953.2 0.674 0.308 12.9 LNU175 24732.2 0.832 0.032 39.4 LNU175 24733.4 0.725 0.105 21.3 LNU19 25151.1 0.881 0.006 47.6 LNU19 25153.3 0.746 0.119 25.0 LNU215 24664.2 0.846 0.000 41.8 LNU215 24663.4 0.735 0.007 23.1 LNU215 24663.3 0.648 0.325 8.5 LNU27 24873.1 0.899 0.039 50.5 LNU27 24873.4 0.742 0.035 24.3 LNU27 24872.4 0.647 0.344 8.3 LNU44 24924.3 1.069 0.023 79.0 LNU44 24924.2 0.826 0.027 38.3 LNU44 24922.3 0.706 0.156 18.2 LNU54 24903.5 1.040 0.002 74.1 LNU54 24901.2 0.902 0.042 51.1 LNU54 24903.3 0.743 0.098 24.5 LNU79 24884.4 0.963 0.010 61.3 LNU79 24881.1 0.850 0.006 42.4 LNU79 24884.3 0.742 0.061 24.3 LNU79 24882.2 0.666 0.164 11.5 CONTROL — 0.764 — 0.0 LNU109 24891.5 1.021 0.020 33.7 LNU109 24892.5 0.939 0.200 22.9 LNU109 24891.2 0.908 0.308 18.8 LNU109 24892.6 0.882 0.367 15.5 LNU110 24952.1 1.492 0.000 95.2 LNU110 24953.2 1.101 0.014 44.1 LNU110 24952.3 1.054 0.094 37.9 LNU133 24744.3 1.192 0.002 56.1 LNU133 24741.1 1.023 0.009 33.9 LNU133 24741.2 0.961 0.005 25.8 LNU133 24744.2 0.795 0.706 4.0 LNU19 25151.1 1.069 0.003 39.9 LNU27 24873.4 1.224 0.000 60.2 LNU44 24922.3 1.153 0.000 50.9 LNU44 24924.3 0.915 0.236 19.8 LNU44 24923.1 0.820 0.501 7.3 LNU54 24901.2 1.131 0.002 48.1 LNU54 24903.5 1.035 0.037 35.4 LNU54 24902.4 0.938 0.009 22.7 LNU6 24994.5 1.104 0.015 44.5 LNU6 24992.3 1.026 0.021 34.2 LNU79 24884.4 1.154 0.001 51.0 LNU79 24881.1 1.031 0.029 34.9 LNU79 24882.2 0.958 0.080 25.3 LNU79 24884.3 0.855 0.382 12.0 CONTROL — 0.512 — 0.0 LNU109 24891.2 1.067 0.004 108.5 LNU109 24892.8 1.053 0.000 105.8 LNU109 24891.5 0.737 0.082 43.9 LNU109 24892.5 0.600 0.244 17.2 LNU143 25975.3 0.755 0.030 47.5 LNU143 25972.1 0.734 0.029 43.3 LNU143 25975.2 0.694 0.055 35.6 LNU143 25971.5 0.623 0.129 21.7 LNU143 25971.2 0.560 0.491 9.5 LNU154 14604.7 0.936 0.002 82.9 LNU154 14604.6 0.843 0.015 64.7 LNU154 14601.6 0.804 0.070 57.1 LNU154 14602.8 0.692 0.156 35.2 LNU154 14604.4 0.672 0.077 31.2 LNU196 25532.2 1.156 0.001 125.8 LNU196 25534.1 0.890 0.025 73.9 LNU196 25531.2 0.727 0.028 42.0 LNU196 25532.1 0.626 0.373 22.2 LNU207 24642.5 0.947 0.003 85.0 LNU207 24642.4 0.914 0.004 78.5 LNU207  24644.18 0.804 0.009 57.1 LNU207  24644.13 0.561 0.593 9.5 LNU207 24641.1 0.532 0.760 4.0 LNU288  14562.12 0.735 0.024 43.5 LNU288 14562.7 0.708 0.037 38.2 LNU288 14562.1 0.658 0.173 28.5 LNU288 14564.9 0.637 0.101 24.5 LNU288 14562.9 0.633 0.180 23.6 LNU50 26024.2 0.863 0.013 68.6 LNU50 26023.2 0.740 0.016 44.6 LNU50 26025.4 0.644 0.088 25.8 LNU50 26022.1 0.577 0.407 12.7 LNU50 26023.5 0.559 0.452 9.2 LNU52 25723.2 1.263 0.000 146.7 LNU52 25721.4 0.968 0.048 89.0 LNU52 25721.3 0.888 0.006 73.4 LNU52 25723.1 0.534 0.750 4.4 CONTROL — 0.646 — 0.0 LNU143 25975.2 0.707 0.290 9.4 LNU154 14602.8 0.829 0.010 28.2 LNU154 14604.4 0.759 0.253 17.4 LNU154 14601.6 0.708 0.296 9.6 LNU207 24642.5 1.001 0.002 54.9 LNU207 24641.1 0.823 0.047 27.3 LNU207 24642.4 0.718 0.180 11.1 LNU211 24774.4 2.327 0.386 260.0 LNU52 25721.1 0.934 0.011 44.5 LNU52 25723.2 0.872 0.025 34.8 LNU52 25723.1 0.848 0.118 31.2 LNU52 25721.2 0.771 0.151 19.3 LNU69 14571.1 0.824 0.041 27.5 LNU69 14572.9 0.790 0.167 22.2 LNU69 14572.8 0.759 0.195 17.4 CONTROL — 0.727 — 0.0 LNU150 24842.9 1.108 0.000 52.3 LNU150 24841.9 0.795 0.437 9.3 LNU179 24632.5 0.939 0.038 29.0 LNU179 24631.9 0.785 0.612 7.9 LNU232 26003.7 0.798 0.443 9.7 LNU235 26184.4 0.947 0.035 30.2 LNU235 26185.3 0.941 0.203 29.4 LNU242 25473.1 0.907 0.012 24.6 LNU242 25474.1 0.783 0.529 7.6 LNU242 25471.1 0.747 0.760 2.7 LNU76 26423.1 0.971 0.002 33.5 LNU76 26421.2 0.836 0.200 14.9 LNU76 26425.1 0.832 0.444 14.3 LNU95  13985.11 0.973 0.012 33.8 LNU95  13985.12 0.801 0.537 10.2 CONTROL — 0.678 — 0.0 LNU118 14013.6 0.809 0.165 19.4 LNU118  14012.15 0.784 0.111 15.7 LNU150 24841.9 0.798 0.251 17.8 LNU150 24841.6 0.753 0.467 11.1 LNU150 24842.9 0.714 0.775 5.4 LNU179 24631.6 0.828 0.134 22.2 LNU179 24631.7 0.812 0.089 19.9 LNU179 24632.7 0.736 0.202 8.6 LNU179 24631.9 0.709 0.743 4.6 LNU232 26001.5 0.814 0.170 20.2 LNU232 26003.3 0.707 0.611 4.3 LNU235 26185.2 1.143 0.000 68.7 LNU235 26184.4 1.125 0.000 66.0 LNU235 26184.2 0.975 0.001 44.0 LNU242 25474.1 0.884 0.056 30.5 LNU288 14563.9 0.967 0.029 42.8 LNU288 14562.1 0.937 0.025 38.3 LNU288 14564.9 0.838 0.020 23.6 LNU288 14562.7 0.781 0.228 15.2 LNU76 26421.2 0.880 0.269 29.8 LNU76 26423.1 0.838 0.247 23.7 LNU76 26422.2 0.824 0.154 21.6 LNU95  13985.16 1.257 0.001 85.6 LNU95  13985.15 1.211 0.000 78.7 LNU95  13985.12 0.949 0.003 40.1 LNU95  13985.19 0.745 0.358 9.9 CONTROL — 0.644 — 0.0 LNU101 27632.7 0.828 0.020 28.6 LNU101 27632.1 0.664 0.486 3.2 LNU128 26515.3 0.894 0.004 38.8 LNU192 28315.2 0.798 0.011 23.9 LNU192 28313.2 0.657 0.721 2.1 LNU206 27621.2 0.750 0.086 16.5 LNU211 24771.1 0.708 0.169 10.0 LNU282 27563.3 0.835 0.029 29.7 LNU282 27563.1 0.800 0.089 24.3 LNU282 27562.1 0.750 0.319 16.5 LNU69 14571.1 0.896 0.001 39.3 LNU69 14572.9 0.696 0.553 8.1 LNU75 27572.1 0.745 0.054 15.7 LNU75 27572.2 0.730 0.246 13.5 CONTROL — 0.564 — 0.0 LNU206 27621.2 0.981 0.131 73.9 LNU206 27621.1 0.863 0.037 52.9 LNU206 27622.1 0.791 0.037 40.2 LNU206 27622.4 0.707 0.099 25.3 LNU249 26153.1 0.869 0.008 54.0 LNU249 26154.2 0.738 0.044 30.7 LNU249 26152.4 0.605 0.555 7.2 LNU282 27563.1 0.761 0.014 34.7 LNU282 27565.2 0.753 0.097 33.4 LNU288 14563.9 0.883 0.000 56.4 LNU288 14564.8 0.854 0.009 51.2 LNU288 14562.9 0.698 0.015 23.6 LNU288 14563.6 0.634 0.331 12.3 LNU75 27572.3 0.949 0.000 68.1 LNU75 27572.2 0.829 0.064 46.9 LNU75 27571.4 0.795 0.000 40.8 LNU75 27571.2 0.781 0.005 38.3 CONTROL — 0.721 — 0.0 LNU11 28204.3 0.762 0.570 5.7 LNU112 28212.4 0.757 0.585 5.0 LNU14 27823.2 0.776 0.442 7.7 LNU183 24863.1 0.926 0.009 28.4 LNU183  24863.12 0.915 0.019 26.9 LNU183 24864.6 0.812 0.539 12.7 LNU183 24865.1 0.795 0.318 10.3 LNU201 28223.1 0.821 0.208 14.0 LNU201 28222.2 0.746 0.733 3.6 LNU268 26044.2 0.805 0.386 11.7 LNU268 26045.1 0.761 0.572 5.6 CONTROL — 0.666 — 0.0 LNU11 28205.1 0.858 0.048 28.9 LNU11 28204.1 0.729 0.372 9.5 LNU11 28205.2 0.708 0.399 6.3 LNU112 28212.4 0.772 0.015 16.0 LNU112 28212.1 0.760 0.022 14.1 LNU112 28212.3 0.690 0.781 3.7 LNU14 27821.3 0.826 0.009 24.1 LNU14 27821.4 0.813 0.053 22.2 LNU14 27824.2 0.708 0.564 6.4 LNU183 24864.6 1.097 0.018 64.7 LNU183  24863.12 0.968 0.016 45.5 LNU183 24865.1 0.954 0.031 43.4 LNU183 24863.1 0.881 0.002 32.3 LNU191 28325.4 0.775 0.076 16.3 LNU191 28324.2 0.756 0.146 13.5 LNU191 28321.3 0.690 0.556 3.6 LNU201 28222.2 0.929 0.017 39.6 LNU201 28223.3 0.788 0.167 18.3 LNU268 26041.4 0.741 0.203 11.2 LNU268 26043.4 0.722 0.338 8.5 CONTROL — 0.523 — 0.0 LNU107 14583.8 0.794 0.010 51.7 LNU107 14585.5 0.656 0.055 25.4 LNU107 14584.9 0.597 0.505 14.2 LNU116 14494.5 0.877 0.002 67.7 LNU116 14492.9 0.728 0.082 39.1 LNU116 14492.5 0.664 0.045 27.0 LNU116 14493.6 0.550 0.734 5.1 LNU121 25642.2 0.892 0.013 70.5 LNU121 27711.1 0.880 0.001 68.2 LNU121 27713.4 0.878 0.000 67.7 LNU121 27713.1 0.799 0.055 52.7 LNU126 25343.1 0.723 0.170 38.2 LNU126 25345.1 0.713 0.065 36.3 LNU126 25343.3 0.638 0.325 21.9 LNU158 27433.3 0.797 0.030 52.4 LNU158 27433.2 0.793 0.055 51.5 LNU158 27432.5 0.670 0.383 28.1 LNU177 24762.6 0.950 0.000 81.6 LNU177 24764.9 0.637 0.256 21.7 LNU177 24765.2 0.564 0.702 7.7 LNU182 25384.1 0.855 0.016 63.4 LNU182 25384.5 0.649 0.148 24.1 LNU182 25384.2 0.641 0.348 22.5 LNU182 27521.4 0.640 0.063 22.4 LNU2 27842.1 0.621 0.249 18.7 LNU2 25713.1 0.585 0.478 11.8 LNU2 27845.2 0.582 0.352 11.3 LNU2 27842.3 0.566 0.556 8.1 LNU225 25991.5 0.686 0.194 31.1 LNU225 25991.2 0.625 0.456 19.6 LNU239 26283.2 0.628 0.351 20.0 LNU239 26284.1 0.602 0.230 15.0 LNU57 27854.5 0.548 0.725 4.7 LNU83 27684.1 0.790 0.021 51.1 CONTROL — 0.400 — 0.0 LNU107 14584.9 0.579 0.031 44.7 LNU107 14585.2 0.511 0.131 27.8 LNU107 14583.8 0.461 0.129 15.2 LNU107 14585.5 0.420 0.690 5.0 LNU116 14492.5 0.713 0.020 78.1 LNU116 14494.5 0.702 0.015 75.3 LNU116 14492.9 0.589 0.061 47.2 LNU116 14493.6 0.563 0.130 40.7 LNU116 14491.5 0.489 0.343 22.2 LNU121 27713.1 0.833 0.031 108.0 LNU121 27711.1 0.636 0.082 58.9 LNU121 27713.4 0.635 0.003 58.8 LNU121 25642.2 0.557 0.065 39.2 LNU126 25343.1 0.559 0.086 39.7 LNU126 25343.3 0.521 0.289 30.1 LNU126 25341.1 0.472 0.329 18.0 LNU158 27433.3 0.898 0.001 124.4 LNU158 27432.5 0.712 0.035 77.8 LNU158 27433.2 0.649 0.056 62.2 LNU158 27434.5 0.415 0.797 3.6 LNU177  24764.12 0.500 0.376 24.8 LNU177 24763.6 0.453 0.543 13.1 LNU177 24762.6 0.449 0.578 12.1 LNU182 25384.6 0.609 0.015 52.2 LNU182 25384.2 0.542 0.059 35.3 LNU2 27842.1 0.653 0.007 63.1 LNU2 27842.3 0.549 0.109 37.1 LNU2 27845.3 0.435 0.627 8.5 LNU225 25991.2 0.693 0.001 73.2 LNU225 25991.3 0.673 0.058 68.2 LNU225 25991.8 0.605 0.000 51.1 LNU225 25991.1 0.456 0.393 13.9 LNU239 26283.2 0.513 0.120 28.2 LNU239 26284.1 0.477 0.331 19.3 LNU239 26284.2 0.468 0.353 16.9 LNU239 26281.1 0.465 0.317 16.1 LNU57 27854.5 0.496 0.354 24.0 LNU57 27852.1 0.478 0.152 19.5 LNU57 27851.2 0.441 0.510 10.1 LNU57 27854.3 0.424 0.779 6.0 LNU83 27685.1 0.793 0.009 98.1 LNU83 27685.2 0.579 0.123 44.7 LNU83 27681.4 0.507 0.120 26.6 CONTROL 12033.3 0.426 — 0.0 LNU129 27501.2 0.681 <0.05 59.9 LNU129 27502.4 0.579 <0.05 36.0 LNU129 27503.4 0.475 <0.6 11.4 LNU129 27504.2 0.779 <0.05 82.9 LNU129 27504.3 0.657 <0.05 54.2 LNU147 27512.1 0.550 <0.05 29.1 LNU147 27513.2 0.554 <0.05 30.1 LNU147 27514.1 0.552 <0.05 29.7 LNU147 27514.2 0.730 <0.05 71.4 LNU153 24851.3 0.621 <0.05 45.9 LNU153 24851.4 0.504 <0.5 18.3 LNU189 26382.3 0.950 <0.05 122.9 LNU189 26382.4 0.779 <0.05 82.9 LNU189 26383.1 0.613 <0.05 43.9 LNU189 26385.1 0.688 <0.05 61.6 LNU189 26385.2 0.493 <0.6 15.8 LNU219 27461.1 0.804 <0.05 88.7 LNU219 27462.1 0.781 <0.05 83.3 LNU219 27462.2 0.903 <0.05 112.0 LNU219 27464.1 0.622 <0.05 46.0 LNU219 27464.2 0.458 <0.6 7.4 LNU256 26211.2 0.519 <0.2 21.8 LNU256 26212.3 0.864 <0.05 102.9 LNU256 26213.1 0.617 <0.05 44.9 LNU256 26214.1 0.667 <0.05 56.6 LNU257 26254.1 0.568 <0.05 33.4 LNU257 26254.3 0.980 <0.05 130.0 LNU257 26254.7 0.842 <0.05 97.6 LNU257 26255.2 0.515 <0.2 20.9 LNU257 26255.3 0.505 <0.05 18.4 LNU261 27401.4 0.527 <0.2 23.7 LNU261 27402.4 0.477 <0.05 11.9 LNU261 27403.2 0.728 <0.05 71.0 LNU261 27405.1 0.609 <0.05 42.9 LNU261 27405.3 0.537 <0.1 26.0 LNU33 25552.2 0.745 <0.05 74.9 LNU33 25553.2 0.571 <0.05 34.1 LNU33 25553.3 0.594 <0.05 39.5 LNU35 27421.2 0.713 <0.05 67.5 LNU35 27422.1 0.556 <0.05 30.4 LNU35 27423.3 0.859 <0.05 101.6 LNU35 27424.3 0.662 <0.05 55.4 LNU35 27424.4 0.593 <0.05 39.2 LNU50 26022.1 0.853 <0.05 100.1 LNU50 26023.2 0.839 <0.05 96.9 LNU50 26023.3 0.501 <0.05 17.6 LNU50 26024.1 0.557 <0.05 30.7 LNU50 26025.3 1.031 <0.05 142.1 LNU70 25311.4 0.835 <0.05 96.0 LNU70 25313.1 0.534 <0.05 25.3 LNU70 25313.2 0.801 <0.05 88.0 LNU70 25315.1 0.501 <0.2 17.7 Table 61.

TABLE 62 Genes showing improved plant performance at nitrogen deficient conditions (T1 generation) Plant Biomass Fresh Plant Biomass Dry Weight Gene Weight [gr.] [gr.] Name Ave. p-value % incr. Gene Name Ave. p-value % incr. CONTROL 0.145 — 0.0 CONTROL 0.008 — 0.0 LNU154 0.146 0.982 0.4 LNU121 0.008 0.715 6.8 CONTROL 0.099 — 0.0 CONTROL 0.005 — 0.0 LNU127 0.106 0.594 7.3 LNU127 0.006 0.595 8.1 LNU188 0.110 0.481 11.4 LNU188 0.005 0.890 2.9 LNU2 0.108 0.419 9.8 LNU239 0.006 0.552 18.1 LNU239 0.110 0.642 11.2 LNU255 0.007 0.245 27.1 LNU255 0.116 0.170 17.9 LNU258 0.006 0.806 6.7 LNU265 0.102 0.740 3.7 LNU265 0.006 0.408 13.8 LNU275 0.137 0.080 39.1 LNU275 0.007 0.079 35.7 LNU58 0.119 0.239 20.6 LNU32 0.008 0.018 45.7 LNU83 0.111 0.621 12.6 LNU58 0.008 0.033 51.9 CONTROL 0.126 — 0.0 CONTROL 0.005 — 0.0 LNU115 0.133 0.698 5.2 LNU176 0.006 0.136 14.0 CONTROL 0.116 — 0.0 LNU284 0.005 0.855 3.2 LNU225 0.127 0.548 9.9 CONTROL 0.006 — 0.0 LNU262 0.128 0.317 10.5 LNU115 0.006 0.775 5.8 LNU59 0.117 0.921 1.6 CONTROL 0.005 — 0.0 LNU60 0.148 0.188 27.9 LNU225 0.005 0.527 9.4 LNU262 0.006 0.081 32.4 LNU266 0.006 0.247 24.4 LNU29 0.005 0.614 10.5 LNU59 0.006 0.195 33.0 LNU60 0.006 0.208 38.9 Table 62. “Ave.”—Average; “% Incr.” = % increment.

TABLE 63 Genes showing improved plant performance at nitrogen deficient conditions (T1 generation) Leaf Area [cm2] Gene Name Time Point Average p-value % increment CONTROL Leaf_Area_TP2 0.283 — 0.0 LNU154 Leaf_Area_TP2 0.290 0.703 2.4 CONTROL Leaf_Area_TP3 0.571 — 0.0 LNU154 Leaf_Area_TP3 0.582 0.817 1.9 CONTROL Leaf_Area_TP1 0.104 — 0.0 LNU127 Leaf_Area_TP1 0.113 0.515 8.3 LNU275 Leaf_Area_TP1 0.156 0.001 49.6 CONTROL Leaf_Area_TP2 0.269 — 0.0 LNU127 Leaf_Area_TP2 0.287 0.447 6.6 LNU2 Leaf_Area_TP2 0.302 0.123 12.4 LNU255 Leaf_Area_TP2 0.272 0.896 1.2 LNU275 Leaf_Area_TP2 0.404 0.000 50.1 LNU83 Leaf_Area_TP2 0.291 0.500 8.1 CONTROL Leaf_Area_TP3 0.639 — 0.0 LNU127 Leaf_Area_TP3 0.647 0.862 1.3 LNU188 Leaf_Area_TP3 0.655 0.867 2.6 LNU2 Leaf_Area_TP3 0.662 0.602 3.6 LNU58 Leaf_Area_TP3 0.714 0.443 11.9 LNU83 Leaf_Area_TP3 0.677 0.705 6.1 CONTROL Leaf_Area_TP1 0.118 — 0.0 LNU123 Leaf_Area_TP1 0.120 0.881 1.5 LNU134 Leaf_Area_TP1 0.138 0.038 17.3 LNU198 Leaf_Area_TP1 0.119 0.901 1.0 CONTROL Leaf_Area_TP2 0.329 — 0.0 LNU134 Leaf_Area_TP2 0.346 0.587 5.1 CONTROL Leaf_Area_TP1 0.097 — 0.0 LNU262 Leaf_Area_TP1 0.120 0.161 23.9 LNU266 Leaf_Area_TP1 0.107 0.475 10.8 LNU59 Leaf_Area_TP1 0.099 0.746 2.7 LNU60 Leaf_Area_TP1 0.102 0.491 5.8 CONTROL Leaf_Area_TP2 0.271 — 0.0 LNU262 Leaf_Area_TP2 0.299 0.009 10.4 LNU60 Leaf_Area_TP2 0.278 0.808 2.6 CONTROL Leaf_Area_TP3 0.567 — 0.0 LNU243 Leaf_Area_TP3 0.573 0.910 1.0 LNU262 Leaf_Area_TP3 0.618 0.253 9.0 LNU60 Leaf_Area_TP3 0.600 0.649 5.7 Table 63.

The genes presented in Tables 64-65 showed a significant improvement in plant NUE since they produced a larger root biomass (root length and root coverage) when grown under limiting nitrogen growth conditions, compared to control plants. Plants producing larger root biomass have better possibilities to absorb larger amount of nitrogen from soil. The genes were cloned under the regulation of a constitutive promoter (At6669) or root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one tissue culture assay. This second experiment confirmed the significant increment in root performance. Event with p-value <0.1 was considered statistically significant

TABLE 64 Genes showing improved root performance at nitrogen deficient conditions (T2 generation) Roots Length [cm] Roots Coverage [cm2] Gene p- Gene p- % Name Event # Ave. value % incr. Name Event # Ave. value incr. CONTROL — 5.460 — 0.0 CONT. — 6.069 — 0.0 LNU100 14474.3 7.008 0.000 28.3 LNU100 14474.3 9.816 0.031 61.7 LNU100 14471.4 6.667 0.013 22.1 LNU100 14473.1 6.948 0.313 14.5 LNU100 14473.1 6.461 0.026 18.3 LNU100 14471.4 6.929 0.190 14.2 LNU100 14474.4 6.309 0.001 15.5 LNU104 25033.3 7.325 0.131 20.7 LNU104 25034.1 6.942 0.283 27.1 LNU104 25034.1 6.679 0.275 10.0 LNU104 25033.3 6.252 0.044 14.5 LNU213 24653.2 9.230 0.002 52.1 LNU104 25033.1 5.902 0.151 8.1 LNU213 24654.4 8.585 0.198 41.4 LNU104 25032.2 5.707 0.571 4.5 LNU213 24653.1 6.920 0.321 14.0 LNU104 25032.1 5.563 0.688 1.9 LNU213 24651.1 6.367 0.523 4.9 LNU213 24653.2 6.677 0.003 22.3 LNU218 24783.2 8.791 0.090 44.8 LNU213 24653.1 6.371 0.056 16.7 LNU218 24781.7 6.766 0.632 11.5 LNU213 24654.4 6.357 0.060 16.4 LNU4 25134.2 7.955 0.057 31.1 LNU213 24651.1 6.202 0.002 13.6 LNU4 25134.1 6.933 0.347 14.2 LNU213 24652.4 6.124 0.053 12.2 LNU4 25131.1 6.521 0.371 7.4 LNU218 24783.2 6.533 0.071 19.6 LNU48 24802.2 10.147 0.001 67.2 LNU218 24781.1 6.273 0.001 14.9 LNU48 24804.4 8.757 0.018 44.3 LNU218 24781.7 5.757 0.545 5.4 LNU48 24802.1 6.538 0.497 7.7 LNU218 24781.2 5.575 0.526 2.1 LNU48 24803.2 6.474 0.601 6.7 LNU4 25131.1 6.811 0.000 24.7 LNU8 25063.1 11.923 0.014 96.4 LNU4 25134.2 6.809 0.000 24.7 LNU8 25063.6 7.772 0.469 28.0 LNU4 25134.1 6.092 0.453 11.6 LNU8 25062.2 6.228 0.714 2.6 LNU4 25133.3 5.643 0.584 3.3 LNU94 24833.3 7.631 0.136 25.7 LNU48 24804.4 6.762 0.001 23.9 LNU94 24834.4 6.753 0.519 11.3 LNU48 24802.2 6.606 0.003 21.0 CONT. — 7.564 — 0.0 LNU48 24803.2 5.911 0.242 8.3 LNU1 24684.1 10.889 0.001 44.0 LNU48 24802.1 5.777 0.362 5.8 LNU1 24682.2 10.883 0.255 43.9 LNU8 25063.1 7.395 0.008 35.4 LNU1 24681.1 10.585 0.067 39.9 LNU8 25062.2 6.064 0.213 11.1 LNU1 24681.3 9.005 0.160 19.0 LNU8 25062.1 5.830 0.105 6.8 LNU1 24682.1 8.490 0.214 12.2 LNU8 25063.6 5.778 0.674 5.8 LNU133 24744.3 13.831 0.022 82.8 LNU94 24833.3 6.716 0.002 23.0 LNU133 24741.1 12.418 0.009 64.2 LNU94 24834.4 6.389 0.022 17.0 LNU133 24741.2 9.300 0.015 22.9 LNU94 24833.1 5.531 0.737 1.3 LNU133 24744.2 8.947 0.166 18.3 CONT. — 6.635 — 0.0 LNU133 24742.2 8.706 0.318 15.1 LNU1 24684.1 7.260 0.000 9.4 LNU175 24732.4 16.185 0.044 114.0 LNU1 24681.1 7.070 0.179 6.6 LNU175 24732.1 15.203 0.003 101.0 LNU133 24744.3 7.399 0.028 11.5 LNU175 24734.4 10.409 0.050 37.6 LNU133 24741.2 7.040 0.003 6.1 LNU175 24731.2 8.880 0.165 17.4 LNU133 24741.1 6.975 0.033 5.1 LNU175 24733.4 8.589 0.374 13.6 LNU133 24742.2 6.937 0.281 4.6 LNU178 14611.5 13.504 0.018 78.5 LNU175 24732.1 7.839 0.003 18.2 LNU178 14611.1 10.597 0.123 40.1 LNU175 24732.4 7.594 0.135 14.5 LNU178 14614.5 10.444 0.173 38.1 LNU175 24734.4 7.437 0.021 12.1 LNU178 14611.4 8.568 0.168 13.3 LNU175 24733.4 6.965 0.158 5.0 LNU178 14612.1 8.562 0.317 13.2 LNU178 14611.5 7.651 0.025 15.3 LNU215 24664.3 12.121 0.051 60.2 LNU178 14614.5 7.431 0.081 12.0 LNU215 24661.4 9.556 0.117 26.3 LNU178 14611.1 7.198 0.027 8.5 LNU215 24664.2 9.327 0.011 23.3 LNU178 14612.1 6.985 0.005 5.3 LNU215 24663.4 8.874 0.121 17.3 LNU178 14611.4 6.889 0.092 3.8 LNU24 24973.1 12.870 0.010 70.1 LNU215 24664.3 7.586 0.001 14.3 LNU24 24971.4 11.398 0.014 50.7 LNU215 24661.4 7.127 0.146 7.4 LNU24 24971.2 10.449 0.001 38.1 LNU215 24664.2 7.087 0.002 6.8 LNU24 24972.1 8.338 0.479 10.2 LNU215 24663.4 7.006 0.167 5.6 LNU24 24971.3 8.036 0.493 6.2 LNU24 24973.1 7.751 0.000 16.8 LNU6 24992.3 12.812 0.028 69.4 LNU24 24971.4 7.021 0.243 5.8 LNU6 24994.2 10.067 0.055 33.1 LNU6 24992.3 7.266 0.108 9.5 LNU6 24993.3 9.314 0.126 23.1 LNU6 24994.2 7.159 0.021 7.9 LNU6 24994.5 9.037 0.390 19.5 LNU6 24994.5 7.027 0.388 5.9 LNU6 24994.1 8.410 0.406 11.2 LNU82 24823.1 7.050 0.186 6.3 LNU82 24823.1 10.020 0.110 32.5 LNU82 24824.2 7.029 0.092 5.9 LNU82 24824.2 9.584 0.087 26.7 LNU82 24824.3 6.741 0.511 1.6 LNU82 24824.3 8.475 0.310 12.0 LNU9 25001.1 7.345 0.072 10.7 LNU82 24824.1 8.462 0.562 11.9 LNU9 25003.1 7.308 0.021 10.2 LNU9 25001.1 10.896 0.012 44.0 LNU9 25001.3 7.027 0.076 5.9 LNU9 25003.1 10.296 0.099 36.1 LNU9 25001.2 6.762 0.730 1.9 LNU9 25001.2 9.602 0.217 26.9 CONT. — 6.780 — 0.0 LNU9 25001.3 9.441 0.085 24.8 LNU120 25463.7 7.505 0.017 10.7 CONT. — 7.438 — 0.0 LNU120 25463.3 7.104 0.329 4.8 LNU120 25463.7 11.666 0.000 56.8 LNU124 14502.1 7.180 0.348 5.9 LNU120 25463.3 8.314 0.249 11.8 LNU132 14102.7 7.563 0.022 11.6 LNU124 14502.1 9.538 0.258 28.2 LNU132 14102.9 7.351 0.021 8.4 LNU124 14501.7 9.283 0.341 24.8 LNU140 14112.6 7.272 0.087 7.3 LNU124 14502.7 8.218 0.448 10.5 LNU140 14112.7 7.233 0.076 6.7 LNU124 14501.1 7.888 0.721 6.0 LNU140 14114.8 7.140 0.189 5.3 LNU132 14102.7 9.324 0.165 25.4 LNU140 14111.6 6.988 0.530 3.1 LNU132 14102.9 9.217 0.025 23.9 LNU180 24724.3 7.931 0.000 17.0 LNU140 14112.7 12.797 0.001 72.0 LNU180 24723.3 6.980 0.532 3.0 LNU140 14111.6 9.362 0.025 25.9 LNU20 24932.4 6.886 0.733 1.6 LNU140 14112.6 7.974 0.374 7.2 LNU36 25562.3 7.270 0.279 7.2 LNU140 14114.8 7.954 0.540 6.9 LNU36 25562.4 7.219 0.142 6.5 LNU180 24724.3 13.032 0.003 75.2 CONT. — 6.252 — 0.0 LNU180 24723.3 10.374 0.006 39.5 LNU1 24682.1 7.163 0.035 14.6 LNU180 24721.4 7.814 0.644 5.1 LNU1 24681.1 7.118 0.033 13.8 LNU20 24932.4 9.646 0.029 29.7 LNU1 24684.1 6.592 0.311 5.4 LNU20 24933.2 8.359 0.594 12.4 LNU110 24953.2 7.215 0.025 15.4 LNU36 25562.3 11.458 0.143 54.0 LNU110 24954.3 6.459 0.513 3.3 LNU36 25562.4 8.949 0.356 20.3 LNU110 24952.3 6.390 0.745 2.2 LNU71 25853.4 9.497 0.169 27.7 LNU175 24734.4 6.980 0.074 11.6 CONT. — 7.471 — 0.0 LNU175 24732.2 6.789 0.217 8.6 LNU1 24682.1 7.871 0.605 5.3 LNU175 24732.1 6.684 0.291 6.9 LNU110 24952.3 9.457 0.430 26.6 LNU175 24733.4 6.405 0.644 2.4 LNU110 24953.2 7.893 0.671 5.6 LNU215 24664.2 7.333 0.014 17.3 LNU175 24732.2 10.614 0.087 42.1 LNU215 24663.4 7.264 0.028 16.2 LNU175 24732.1 8.454 0.362 13.1 LNU215 24661.4 7.235 0.020 15.7 LNU19 25151.1 8.732 0.331 16.9 LNU215 24663.3 7.010 0.122 12.1 LNU215 24664.2 10.890 0.014 45.8 LNU215 24663.1 6.620 0.320 5.9 LNU215 24663.4 9.659 0.016 29.3 LNU27 24873.1 7.237 0.033 15.8 LNU215 24663.3 8.611 0.239 15.2 LNU27 24873.4 6.541 0.520 4.6 LNU215 24661.4 8.607 0.103 15.2 LNU27 24871.4 6.422 0.617 2.7 LNU27 24873.1 11.099 0.106 48.5 LNU44 24923.3 7.316 0.022 17.0 LNU27 24873.4 8.805 0.231 17.8 LNU44 24924.2 7.272 0.018 16.3 LNU44 24924.2 11.478 0.024 53.6 LNU44 24922.3 7.169 0.045 14.7 LNU44 24924.3 10.805 0.114 44.6 LNU54 24901.2 7.648 0.030 22.3 LNU44 24922.3 10.586 0.205 41.7 LNU54 24902.4 7.438 0.010 19.0 LNU44 24923.3 9.478 0.026 26.9 LNU54 24903.5 7.013 0.120 12.2 LNU54 24903.5 12.998 0.000 74.0 LNU54 24903.3 6.934 0.256 10.9 LNU54 24901.2 11.545 0.124 54.5 LNU54 24902.7 6.461 0.603 3.3 LNU54 24903.3 11.231 0.101 50.3 LNU79 24882.2 7.312 0.018 16.9 LNU54 24902.4 9.290 0.026 24.3 LNU79 24881.1 7.287 0.017 16.5 LNU79 24884.4 11.593 0.001 55.2 LNU79 24884.4 7.052 0.043 12.8 LNU79 24881.1 11.528 0.010 54.3 LNU79 24883.2 6.742 0.224 7.8 LNU79 24884.3 9.294 0.179 24.4 CONT. — 6.833 — 0.0 LNU79 24882.2 8.705 0.104 16.5 LNU109 24892.8 7.289 0.058 6.7 CONT. — 8.911 — 0.0 LNU109 24891.5 7.107 0.314 4.0 LNU109 24891.5 11.274 0.022 26.5 LNU110 24952.1 8.060 0.001 18.0 LNU109 24892.6 10.560 0.281 18.5 LNU110 24952.3 6.969 0.733 2.0 LNU109 24891.2 9.241 0.800 3.7 LNU133 24744.3 7.713 0.005 12.9 LNU110 24952.1 19.086 0.000 114.2 LNU133 24741.1 7.500 0.051 9.8 LNU110 24952.3 12.178 0.071 36.7 LNU133 24742.2 6.891 0.785 0.8 LNU110 24953.2 10.598 0.334 18.9 LNU19 25151.1 7.230 0.230 5.8 LNU110 24954.3 9.930 0.306 11.4 LNU27 24873.4 7.547 0.015 10.5 LNU133 24744.3 14.915 0.004 67.4 LNU27 24871.4 7.040 0.366 3.0 LNU133 24741.1 12.618 0.097 41.6 LNU44 24922.3 7.636 0.008 11.8 LNU133 24742.2 10.314 0.139 15.7 LNU54 24901.2 7.770 0.003 13.7 LNU133 24741.2 9.795 0.366 9.9 LNU54 24903.5 6.959 0.693 1.9 LNU19 25151.1 12.769 0.053 43.3 LNU6 24992.3 7.592 0.020 11.1 LNU27 24873.4 14.340 0.000 60.9 LNU6 24994.5 7.248 0.156 6.1 LNU44 24922.3 16.486 0.000 85.0 LNU79 24884.4 7.615 0.008 11.4 LNU54 24901.2 14.207 0.007 59.4 LNU79 24881.1 7.315 0.048 7.1 LNU54 24903.5 10.705 0.215 20.1 LNU79 24882.2 6.938 0.704 1.5 LNU6 24992.3 14.206 0.025 59.4 CONT. — 6.439 — 0.0 LNU6 24994.5 11.407 0.229 28.0 LNU109 24892.8 7.505 0.066 16.6 LNU6 24994.2 9.941 0.232 11.6 LNU109 24891.5 6.844 0.408 6.3 LNU79 24884.4 15.230 0.000 70.9 LNU143 25975.3 7.404 0.086 15.0 LNU79 24881.1 11.673 0.018 31.0 LNU143 25972.1 7.221 0.137 12.1 LNU79 24882.2 10.918 0.273 22.5 LNU143 25971.2 6.746 0.523 4.8 LNU79 24884.3 10.381 0.258 16.5 LNU143 25971.5 6.725 0.555 4.4 LNU79 24883.2 9.300 0.577 4.4 LNU154 14604.7 7.068 0.230 9.8 CONT. — 6.329 — 0.0 LNU154 14604.6 6.971 0.293 8.3 LNU109 24892.8 12.163 0.002 92.2 LNU154 14601.6 6.857 0.438 6.5 LNU109 24891.5 9.351 0.067 47.8 LNU196 25532.2 7.657 0.044 18.9 LNU109 24891.2 9.220 0.134 45.7 LNU196 25534.1 7.153 0.231 11.1 LNU143 25975.3 8.893 0.016 40.5 LNU196 25533.1 6.825 0.414 6.0 LNU143 25972.1 8.480 0.043 34.0 LNU196 25532.1 6.745 0.628 4.7 LNU143 25975.2 7.944 0.277 25.5 LNU207 24642.5 7.512 0.065 16.7 LNU143 25971.5 7.539 0.396 19.1 LNU207 24644.18 7.441 0.076 15.6 LNU154 14601.6 9.541 0.108 50.8 LNU207 24642.4 7.339 0.109 14.0 LNU154 14604.6 9.238 0.039 46.0 LNU207 24644.13 6.858 0.410 6.5 LNU154 14604.7 8.969 0.032 41.7 LNU288 14564.9 7.527 0.062 16.9 LNU154 14602.8 8.206 0.375 29.7 LNU288 14562.1 7.058 0.217 9.6 LNU196 25532.2 14.062 0.001 122.2 LNU288 14562.7 6.960 0.350 8.1 LNU196 25534.1 11.123 0.166 75.8 LNU288 14562.9 6.822 0.401 5.9 LNU196 25532.1 8.240 0.335 30.2 LNU50 26023.2 7.381 0.093 14.6 LNU196 25531.2 6.924 0.550 9.4 LNU50 26023.5 7.254 0.124 12.7 LNU196 25533.1 6.629 0.666 4.7 LNU50 26024.2 7.129 0.249 10.7 LNU207 24642.4 11.713 0.059 85.1 LNU50 26025.3 6.750 0.499 4.8 LNU207 24642.5 10.786 0.013 70.4 LNU52 25723.2 7.754 0.034 20.4 LNU207 24644.18 9.470 0.036 49.6 LNU52 25721.4 7.203 0.191 11.9 LNU207 24644.13 8.136 0.302 28.6 LNU52 25723.1 6.913 0.377 7.3 LNU288 14562.1 8.997 0.162 42.2 LNU52 25721.3 6.720 0.614 4.4 LNU288 14562.7 8.395 0.113 32.6 CONT. — 5.633 — 0.0 LNU288 14564.9 8.299 0.036 31.1 LNU143 25975.2 6.753 0.015 19.9 LNU288 14562.12 7.258 0.206 14.7 LNU143 25975.3 6.608 0.003 17.3 LNU288 14562.9 7.135 0.346 12.7 LNU143 25971.5 6.566 0.020 16.6 LNU50 26023.2 9.476 0.034 49.7 LNU143 25972.1 6.543 0.041 16.1 LNU50 26024.2 9.283 0.125 46.7 LNU143 25971.2 6.461 0.006 14.7 LNU50 26025.4 8.172 0.053 29.1 LNU154 14602.8 6.492 0.016 15.2 LNU50 26023.5 7.519 0.204 18.8 LNU154 14601.6 6.149 0.108 9.2 LNU50 26022.1 6.843 0.599 8.1 LNU207 24642.5 6.965 0.011 23.6 LNU52 25723.2 14.598 0.005 130.7 LNU207 24641.1 6.872 0.016 22.0 LNU52 25721.4 10.374 0.100 63.9 LNU207 24642.4 6.413 0.011 13.8 LNU52 25721.3 10.089 0.085 59.4 LNU211 24771.1 7.033 0.007 24.8 LNU52 25723.1 7.096 0.545 12.1 LNU211 24771.3 6.030 0.095 7.0 CONT. — 8.555 — 0.0 LNU211 24774.4 5.978 0.569 6.1 LNU143 25975.2 9.977 0.289 16.6 LNU52 25723.1 7.106 0.004 26.1 LNU143 25975.3 9.097 0.708 6.3 LNU52 25721.2 6.927 0.005 23.0 LNU154 14602.8 10.155 0.142 18.7 LNU52 25721.1 6.506 0.021 15.5 LNU207 24642.5 11.122 0.079 30.0 LNU52 25723.2 5.812 0.660 3.2 LNU207 24641.1 10.558 0.138 23.4 LNU69 14571.1 7.049 0.003 25.1 LNU207 24642.4 9.609 0.289 12.3 LNU69 14573.3 6.658 0.008 18.2 LNU211 24771.1 9.940 0.183 16.2 LNU69 14572.9 6.285 0.020 11.6 LNU52 25721.1 12.111 0.083 41.6 LNU69 14572.8 6.259 0.025 11.1 LNU52 25723.1 11.473 0.179 34.1 CONT. — 5.748 — 0.0 LNU52 25721.2 11.153 0.205 30.4 LNU150 24842.9 7.210 0.000 25.4 LNU52 25723.2 10.026 0.431 17.2 LNU150 24841.9 7.204 0.001 25.3 LNU69 14571.1 11.815 0.106 38.1 LNU150 24843.5 6.754 0.062 17.5 LNU69 14572.9 9.516 0.423 11.2 LNU179 24632.5 7.693 0.000 33.8 LNU69 14572.8 9.471 0.279 10.7 LNU179 24631.9 7.481 0.004 30.1 CONT. — 7.365 — 0.0 LNU179 24631.6 6.733 0.008 17.1 LNU150 24842.9 13.108 0.000 78.0 LNU179 24631.7 6.139 0.210 6.8 LNU150 24841.9 9.862 0.067 33.9 LNU232 26003.3 6.837 0.002 18.9 LNU150 24843.5 9.813 0.252 33.2 LNU232 26001.5 6.830 0.057 18.8 LNU179 24632.5 12.877 0.028 74.8 LNU232 26003.7 6.060 0.359 5.4 LNU179 24631.9 10.523 0.117 42.9 LNU232 26001.2 6.004 0.436 4.5 LNU179 24631.6 7.714 0.754 4.7 LNU235 26184.4 7.751 0.000 34.8 LNU232 26003.7 9.269 0.098 25.9 LNU235 26185.3 7.381 0.005 28.4 LNU232 26003.3 7.728 0.720 4.9 LNU235 26182.1 6.699 0.017 16.5 LNU235 26184.4 13.577 0.001 84.3 LNU235 26184.2 6.546 0.026 13.9 LNU235 26185.3 11.955 0.064 62.3 LNU235 26185.2 6.094 0.276 6.0 LNU235 26182.1 8.994 0.179 22.1 LNU242 25474.1 7.362 0.001 28.1 LNU235 26184.2 8.691 0.167 18.0 LNU242 25473.1 7.108 0.003 23.7 LNU242 25473.1 12.344 0.000 67.6 LNU242 25473.3 6.390 0.073 11.2 LNU242 25474.1 10.746 0.086 45.9 LNU242 25471.1 6.244 0.148 8.6 LNU76 26425.1 11.223 0.020 52.4 LNU242 25472.1 5.879 0.763 2.3 LNU76 26421.2 10.070 0.047 36.7 LNU76 26425.1 7.027 0.001 22.2 LNU76 26423.1 9.805 0.046 33.1 LNU76 26423.1 6.864 0.017 19.4 LNU76 26421.1 8.691 0.466 18.0 LNU76 26421.2 6.813 0.066 18.5 LNU95 13985.11 12.944 0.033 75.7 LNU76 26421.1 6.590 0.106 14.6 LNU95 13985.15 9.432 0.058 28.1 LNU95 13985.11 7.431 0.000 29.3 LNU95 13985.12 9.399 0.182 27.6 LNU95 13985.19 7.114 0.004 23.8 LNU95 13985.19 9.281 0.368 26.0 LNU95 13985.15 6.928 0.001 20.5 LNU95 13985.16 7.914 0.569 7.5 LNU95 13985.12 6.791 0.036 18.1 CONT. — 9.009 — 0.0 LNU95 13985.16 6.612 0.048 15.0 LNU232 26001.5 11.019 0.177 22.3 CONT. — 6.930 — 0.0 LNU235 26184.4 14.496 0.000 60.9 LNU179 24631.6 7.162 0.374 3.4 LNU235 26185.2 14.127 0.017 56.8 LNU232 26001.5 7.624 0.145 10.0 LNU235 26184.2 10.838 0.207 20.3 LNU232 26003.3 7.555 0.005 9.0 LNU242 25474.1 10.306 0.406 14.4 LNU235 26184.4 8.109 0.000 17.0 LNU288 14563.9 12.963 0.135 43.9 LNU235 26184.2 7.760 0.006 12.0 LNU288 14562.1 10.884 0.044 20.8 LNU235 26185.2 7.656 0.031 10.5 LNU288 14564.9 10.080 0.495 11.9 LNU242 25474.1 7.198 0.532 3.9 LNU76 26421.2 11.857 0.344 31.6 LNU288 14564.9 7.294 0.201 5.3 LNU76 26422.2 9.715 0.723 7.8 LNU288 14562.7 7.126 0.571 2.8 LNU76 26423.1 9.480 0.777 5.2 LNU288 14563.6 7.066 0.547 2.0 LNU95 13985.16 13.851 0.037 53.7 LNU288 14563.9 7.050 0.623 1.7 LNU95 13985.12 12.566 0.179 39.5 LNU76 26421.2 7.262 0.303 4.8 LNU95 13985.15 12.253 0.037 36.0 LNU95 13985.16 7.835 0.000 13.1 CONT. — 7.303 — 0.0 LNU95 13985.15 7.095 0.521 2.4 LNU101 27632.7 10.044 0.030 37.5 CONT. — 6.277 — 0.0 LNU101 27635.1 8.226 0.494 12.6 LNU101 27632.7 7.595 0.000 21.0 LNU101 27632.1 8.137 0.145 11.4 LNU101 27635.1 6.518 0.421 3.8 LNU128 26515.3 12.337 0.000 68.9 LNU128 26515.3 7.668 0.001 22.2 LNU128 26511.5 9.896 0.028 35.5 LNU128 26511.5 7.477 0.000 19.1 LNU128 26515.2 8.997 0.171 23.2 LNU128 26515.2 6.784 0.237 8.1 LNU128 26511.4 7.501 0.709 2.7 LNU192 28315.2 7.732 0.000 23.2 LNU192 28315.2 11.544 0.001 58.1 LNU192 28313.2 7.474 0.001 19.1 LNU192 28313.2 10.093 0.000 38.2 LNU192 28312.2 6.813 0.031 8.5 LNU192 28313.3 8.887 0.209 21.7 LNU192 28313.3 6.626 0.429 5.6 LNU192 28312.2 7.667 0.532 5.0 LNU206 27621.2 6.916 0.023 10.2 LNU206 27621.2 10.347 0.011 41.7 LNU206 27622.1 6.838 0.191 8.9 LNU206 27621.1 8.702 0.012 19.2 LNU211 24771.1 7.325 0.008 16.7 LNU206 27622.1 8.138 0.108 11.4 LNU282 27562.1 7.580 0.017 20.8 LNU211 24771.1 11.295 0.035 54.7 LNU282 27563.1 7.388 0.005 17.7 LNU211 24773.2 9.318 0.074 27.6 LNU282 27563.3 7.299 0.045 16.3 LNU282 27562.1 12.185 0.026 66.8 LNU282 27565.2 6.768 0.224 7.8 LNU282 27563.3 10.979 0.012 50.3 LNU69 14571.1 7.603 0.000 21.1 LNU282 27563.1 10.436 0.037 42.9 LNU69 14573.5 6.811 0.135 8.5 LNU282 27565.2 8.007 0.266 9.6 LNU75 27572.1 7.450 0.000 18.7 LNU69 14571.1 12.531 0.002 71.6 LNU75 27572.2 7.264 0.069 15.7 LNU69 14573.5 9.289 0.077 27.2 LNU75 27571.4 6.677 0.333 6.4 LNU75 27572.2 11.342 0.094 55.3 LNU75 27572.3 6.590 0.407 5.0 LNU75 27572.1 9.625 0.022 31.8 CONT. — 5.813 — 0.0 LNU75 27572.3 8.378 0.398 14.7 LNU101 27632.5 6.807 0.016 17.1 LNU75 27571.4 7.934 0.591 8.6 LNU101 27632.6 6.150 0.322 5.8 CONT. — 6.735 — 0.0 LNU118 14012.15 5.962 0.626 2.6 LNU101 27632.5 8.284 0.190 23.0 LNU128 26515.3 6.716 0.035 15.5 LNU118 14012.15 8.399 0.071 24.7 LNU128 26511.5 6.226 0.315 7.1 LNU206 27621.2 12.586 0.032 86.9 LNU206 27621.2 7.622 0.001 31.1 LNU206 27622.4 11.079 0.012 64.5 LNU206 27622.4 7.043 0.014 21.2 LNU206 27622.1 10.117 0.052 50.2 LNU206 27622.1 6.757 0.103 16.2 LNU206 27621.1 9.288 0.118 37.9 LNU249 26152.4 6.759 0.189 16.3 LNU249 26153.1 10.203 0.102 51.5 LNU249 26153.1 6.492 0.102 11.7 LNU249 26154.2 9.330 0.208 38.5 LNU249 26151.1 6.359 0.283 9.4 LNU249 26152.4 8.642 0.232 28.3 LNU249 26154.2 6.342 0.316 9.1 LNU282 27563.1 10.545 0.026 56.6 LNU249 26152.2 6.191 0.197 6.5 LNU282 27565.2 10.509 0.072 56.0 LNU282 27565.2 7.232 0.001 24.4 LNU282 27562.1 7.008 0.765 4.1 LNU282 27563.1 6.899 0.017 18.7 LNU288 14563.9 12.005 0.018 78.3 LNU282 27562.1 6.530 0.069 12.3 LNU288 14563.6 9.606 0.173 42.6 LNU282 27565.1 6.410 0.188 10.3 LNU288 14564.8 9.604 0.090 42.6 LNU282 27563.3 6.409 0.205 10.2 LNU288 14562.9 9.080 0.007 34.8 LNU288 14563.6 6.954 0.003 19.6 LNU288 14562.7 8.511 0.202 26.4 LNU288 14562.7 6.914 0.014 18.9 LNU75 27572.2 13.524 0.039 100.8 LNU288 14563.9 6.862 0.016 18.0 LNU75 27571.2 11.853 0.022 76.0 LNU288 14562.9 6.355 0.078 9.3 LNU75 27572.3 11.191 0.014 66.2 LNU288 14564.8 6.291 0.244 8.2 LNU75 27571.4 9.627 0.064 42.9 LNU75 27572.2 7.464 0.003 28.4 CONT. — 11.156 — 0.0 LNU75 27571.2 7.428 0.000 27.8 LNU112 28212.4 12.419 0.271 11.3 LNU75 27571.4 7.346 0.000 26.4 LNU183 24865.1 12.047 0.600 8.0 LNU75 27572.3 7.114 0.001 22.4 LNU183 24863.1 11.863 0.548 6.3 CONT. — 6.748 — 0.0 LNU201 28222.2 12.100 0.653 8.5 LNU11 28205.2 7.162 0.194 6.1 LNU201 28223.1 11.563 0.780 3.6 LNU112 28212.4 7.424 0.065 10.0 LNU268 26044.2 13.230 0.270 18.6 LNU14 27821.3 7.205 0.162 6.8 CONT. — 8.642 — 0.0 LNU14 27823.2 6.881 0.653 2.0 LNU11 28205.2 11.985 0.010 38.7 LNU14 27824.2 6.880 0.664 2.0 LNU11 28203.2 11.222 0.219 29.9 LNU14 27821.1 6.873 0.710 1.8 LNU11 28205.1 11.099 0.083 28.4 LNU201 28223.3 7.200 0.199 6.7 LNU11 28202.5 11.048 0.171 27.8 LNU201 28222.2 7.189 0.180 6.5 LNU11 28204.1 9.232 0.632 6.8 LNU201 28223.1 7.123 0.287 5.6 LNU112 28212.1 11.083 0.103 28.3 LNU201 28222.3 7.105 0.263 5.3 LNU112 28212.4 9.361 0.431 8.3 LNU268 26044.2 7.215 0.173 6.9 LNU14 27821.3 14.480 0.003 67.6 LNU268 26041.6 7.074 0.272 4.8 LNU14 27821.4 11.236 0.153 30.0 CONT. — 6.558 — 0.0 LNU14 27824.2 9.792 0.285 13.3 LNU11 28205.2 7.549 0.054 15.1 LNU14 27821.1 9.067 0.556 4.9 LNU11 28202.5 7.066 0.043 7.7 LNU183 24864.6 16.882 0.000 95.4 LNU11 28205.1 6.967 0.082 6.2 LNU183 24865.1 13.996 0.010 62.0 LNU11 28203.2 6.673 0.705 1.8 LNU183 24863.12 13.932 0.002 61.2 LNU112 28212.1 7.029 0.091 7.2 LNU183 24863.1 11.228 0.071 29.9 LNU112 28212.4 6.855 0.357 4.5 LNU191 28325.4 11.845 0.144 37.1 LNU14 27821.3 7.453 0.004 13.6 LNU191 28323.1 11.545 0.092 33.6 LNU14 27821.4 7.112 0.086 8.4 LNU191 28321.3 10.102 0.059 16.9 LNU14 27824.2 6.705 0.664 2.2 LNU191 28324.2 9.088 0.641 5.2 LNU14 27821.1 6.617 0.785 0.9 LNU201 28222.2 13.603 0.012 57.4 LNU183 24864.6 7.736 0.001 18.0 LNU201 28223.3 12.364 0.053 43.1 LNU183 24863.12 7.306 0.109 11.4 LNU201 28221.3 9.939 0.105 15.0 LNU183 24863.1 6.908 0.265 5.3 LNU201 28223.1 9.431 0.624 9.1 LNU183 24865.1 6.901 0.514 5.2 LNU268 26041.4 10.798 0.011 25.0 LNU201 28222.2 7.686 0.001 17.2 LNU268 26041.6 10.549 0.191 22.1 LNU201 28223.3 7.225 0.075 10.2 LNU268 26043.4 10.366 0.163 20.0 LNU201 28223.1 6.881 0.350 4.9 CONT. — 8.826 — 0.0 LNU268 26041.6 7.361 0.030 12.3 LNU107 14583.8 12.388 0.135 40.4 LNU268 26041.4 7.076 0.043 7.9 LNU107 14585.5 10.429 0.192 18.2 CONT. — 6.688 — 0.0 LNU107 14584.9 9.576 0.645 8.5 LNU107 14585.5 6.948 0.465 3.9 LNU116 14492.9 12.023 0.153 36.2 LNU107 14584.9 6.902 0.582 3.2 LNU116 14494.5 11.609 0.162 31.5 LNU107 14583.8 6.876 0.677 2.8 LNU116 14492.5 10.826 0.224 22.7 LNU121 27711.1 7.515 0.022 12.4 LNU121 27713.4 13.101 0.024 48.4 LNU121 27713.4 7.131 0.040 6.6 LNU121 25642.2 12.536 0.016 42.0 LNU121 25642.2 6.832 0.534 2.2 LNU121 27711.1 12.183 0.025 38.0 LNU126 25345.1 7.223 0.030 8.0 LNU121 27713.1 9.357 0.718 6.0 LNU126 25343.1 7.063 0.039 5.6 LNU126 25345.1 12.082 0.186 36.9 LNU126 25343.3 6.914 0.580 3.4 LNU126 25343.1 11.624 0.066 31.7 LNU158 27433.3 7.724 0.001 15.5 LNU126 25343.3 10.159 0.512 15.1 LNU158 27433.2 7.263 0.050 8.6 LNU158 27433.3 13.205 0.003 49.6 LNU158 27432.5 7.064 0.448 5.6 LNU158 27432.5 13.036 0.262 47.7 LNU177 24764.9 7.526 0.199 12.5 LNU158 27433.2 11.539 0.083 30.7 LNU177 24762.6 7.459 0.001 11.5 LNU177 24762.6 13.660 0.000 54.8 LNU177 24764.12 7.090 0.429 6.0 LNU177 24764.9 10.753 0.487 21.8 LNU177 24765.2 6.840 0.490 2.3 LNU177 24765.2 9.467 0.570 7.3 LNU182 25384.1 7.669 0.032 14.7 LNU182 25384.1 14.203 0.000 60.9 LNU182 27521.4 7.285 0.044 8.9 LNU182 27521.4 12.084 0.082 36.9 LNU182 25384.5 6.920 0.233 3.5 LNU182 25384.2 9.950 0.536 12.7 LNU2 27842.1 7.230 0.111 8.1 LNU182 25384.5 9.279 0.725 5.1 LNU2 27842.3 6.891 0.222 3.0 LNU2 27842.1 10.901 0.082 23.5 LNU225 25991.5 7.854 0.000 17.4 LNU2 27842.3 10.146 0.166 15.0 LNU225 25991.3 7.318 0.004 9.4 LNU225 25991.5 16.802 0.002 90.4 LNU225 25991.2 7.306 0.164 9.2 LNU225 25991.2 13.379 0.239 51.6 LNU239 26284.1 7.073 0.262 5.8 LNU239 26284.1 10.137 0.231 14.9 LNU57 27852.1 7.119 0.122 6.5 LNU57 27852.1 9.278 0.731 5.1 LNU83 27681.4 7.284 0.166 8.9 LNU83 27681.4 10.944 0.212 24.0 LNU83 27682.1 6.944 0.535 3.8 LNU83 27684.1 9.726 0.592 10.2 CONT. — 6.610 — 0.0 CONT. — 8.649 — 0.0 LNU107 14584.9 7.452 0.011 12.7 LNU107 14584.9 13.777 0.006 59.3 LNU116 14492.5 6.844 0.603 3.5 LNU107 14583.8 10.320 0.189 19.3 LNU121 27711.1 7.402 0.015 12.0 LNU107 14585.2 9.003 0.660 4.1 LNU121 27713.1 7.140 0.136 8.0 LNU116 14492.5 12.926 0.175 49.5 LNU121 27713.4 6.865 0.366 3.9 LNU116 14494.5 11.992 0.193 38.6 LNU121 25642.2 6.793 0.733 2.8 LNU116 14493.6 9.901 0.185 14.5 LNU126 25343.1 7.627 0.015 15.4 LNU121 25642.2 12.625 0.067 46.0 LNU126 25345.1 6.880 0.247 4.1 LNU121 27711.1 12.159 0.059 40.6 LNU126 25343.3 6.774 0.579 2.5 LNU121 27713.1 11.980 0.126 38.5 LNU126 25343.4 6.743 0.602 2.0 LNU121 27713.4 10.723 0.212 24.0 LNU158 27433.3 7.700 0.001 16.5 LNU126 25343.1 12.591 0.061 45.6 LNU158 27432.5 7.579 0.003 14.7 LNU126 25343.3 9.454 0.636 9.3 LNU158 27433.2 7.218 0.174 9.2 LNU126 25343.4 9.346 0.489 8.1 LNU158 27434.5 7.076 0.202 7.1 LNU158 27433.3 14.173 0.003 63.9 LNU177 24764.12 7.403 0.005 12.0 LNU158 27432.5 12.764 0.002 47.6 LNU177 24765.2 7.050 0.223 6.7 LNU158 27433.2 10.182 0.303 17.7 LNU177 24763.6 6.895 0.320 4.3 LNU177 24764.12 12.256 0.002 41.7 LNU182 27521.4 7.048 0.183 6.6 LNU177 24763.6 9.330 0.473 7.9 LNU182 25384.5 6.953 0.377 5.2 LNU177 24762.6 9.229 0.375 6.7 LNU182 25384.2 6.938 0.392 5.0 LNU182 25384.6 9.479 0.435 9.6 LNU182 25384.6 6.861 0.470 3.8 LNU182 25384.1 9.407 0.565 8.8 LNU2 27842.1 7.658 0.002 15.9 LNU182 25384.5 9.310 0.530 7.6 LNU2 27842.3 7.291 0.010 10.3 LNU2 27842.1 12.557 0.031 45.2 LNU2 25713.1 6.781 0.432 2.6 LNU2 27842.3 10.135 0.121 17.2 LNU225 25991.3 7.597 0.009 14.9 LNU2 25713.1 9.741 0.417 12.6 LNU225 25991.1 7.436 0.021 12.5 LNU225 25991.3 14.898 0.000 72.2 LNU225 25991.2 7.232 0.026 9.4 LNU225 25991.2 13.446 0.031 55.5 LNU225 25991.8 7.229 0.041 9.4 LNU225 25991.8 11.180 0.011 29.3 LNU225 25991.5 7.188 0.033 8.7 LNU225 25991.1 10.790 0.067 24.8 LNU239 26284.2 7.240 0.074 9.5 LNU239 26284.2 11.555 0.003 33.6 LNU239 26281.1 7.010 0.093 6.1 LNU239 26281.1 8.866 0.720 2.5 LNU239 26284.1 6.697 0.763 1.3 LNU57 27852.1 13.264 0.000 53.4 LNU57 27852.1 7.461 0.005 12.9 LNU57 27851.2 12.792 0.028 47.9 LNU57 27851.2 7.231 0.067 9.4 LNU57 27854.5 10.651 0.061 23.1 LNU57 27854.3 7.077 0.107 7.1 LNU57 27854.3 9.037 0.488 4.5 LNU57 27854.5 7.063 0.150 6.8 LNU83 27685.1 14.008 0.002 62.0 LNU83 27685.2 7.614 0.010 15.2 LNU83 27685.2 11.664 0.041 34.9 LNU83 27685.1 7.587 0.001 14.8 LNU83 27681.4 11.522 0.020 33.2 LNU83 27681.4 7.289 0.017 10.3 CONT. — 10.064 — LNU83 27682.1 7.010 0.337 6.0 LNU17 13991.1 11.488 0.32 14.1 CONT. — 6.95  — 0.0 CONT. 12033.3 6.301 0.0 LNU17 13991.1 7.33  0.24 5.3 LNU129 27501.2 10.049 <0.05 59.5 LNU17 13991.14 7.11  0.62 2.1 LNU129 27502.4 8.465 <0.05 34.3 CONT. — 6.181 — 0.0 LNU129 27503.4 8.035 <0.05 27.5 LNU129 27501.2 7.291 <0.1 17.9 LNU129 27504.2 9.203 <0.05 46.0 LNU129 27502.4 6.724 <0.1 8.8 LNU129 27504.3 10.684 <0.05 69.6 LNU129 27503.4 6.617 <0.2 7.1 LNU147 27511.4 8.137 <0.05 29.1 LNU129 27504.3 7.254 <0.1 17.4 LNU147 27512.1 7.206 14.4 LNU147 27511.4 6.549 <0.5 5.9 LNU147 27513.2 9.441 <0.05 49.8 LNU147 27512.1 6.521 <0.5 5.5 LNU147 27514.1 8.236 <0.05 30.7 LNU147 27514.2 6.686 <0.1 8.2 LNU147 27514.2 9.705 <0.05 54.0 LNU189 26382.4 7.221 <0.1 16.8 LNU153 24851.3 7.510 19.2 LNU189 26383.1 6.520 <0.5 5.5 LNU153 24851.4 7.033 11.6 LNU189 26385.1 6.833 <0.1 10.5 LNU189 26382.3 11.910 <0.05 89.0 LNU219 27462.1 7.278 <0.1 17.7 LNU189 26382.4 12.085 <0.05 91.8 LNU219 27462.2 6.981 <0.1 12.9 LNU189 26383.1 9.119 <0.05 44.7 LNU256 26211.2 6.754 <0.1 9.3 LNU189 26385.1 10.337 <0.05 64.0 LNU256 26212.3 6.691 <0.1 8.2 LNU219 27461.1 9.304 <0.05 47.7 LNU256 26214.1 7.064 <0.1 14.3 LNU219 27462.1 14.273 <0.05 126.5 LNU257 26254.1 7.230 <0.1 17.0 LNU219 27462.2 11.156 <0.05 77.1 LNU257 26254.3 7.714 <0.1 24.8 LNU219 27464.2 7.151 13.5 LNU257 26255.2 6.760 <0.1 9.4 LNU256 26211.2 7.359 16.8 LNU257 26255.3 6.777 <0.1 9.6 LNU256 26212.3 10.694 <0.05 69.7 LNU261 27401.4 7.082 <0.1 14.6 LNU256 26213.1 9.008 <0.05 43.0 LNU261 27403.2 6.719 <0.1 8.7 LNU256 26214.1 11.063 <0.05 75.6 LNU261 27405.1 6.970 <0.1 12.8 LNU257 26254.1 9.639 <0.05 53.0 LNU261 27405.3 6.748 <0.1 9.2 LNU257 26254.3 15.465 <0.05 145.4 LNU33 25552.2 6.847 <0.1 10.8 LNU257 26254.7 9.843 <0.05 56.2 LNU33 25553.3 6.888 <0.1 11.4 LNU257 26255.2 6.589 <0.8 4.6 LNU35 27421.2 6.636 <0.2 7.4 LNU257 26255.3 7.862 <0.2 24.8 LNU35 27423.3 6.966 <0.1 12.7 LNU261 27401.4 8.612 <0.05 36.7 LNU35 27424.3 6.633 <0.2 7.3 LNU261 27403.2 9.379 <0.05 48.8 LNU50 26022.1 6.629 <0.2 7.2 LNU261 27405.1 8.806 <0.05 39.8 LNU50 26023.2 6.948 <0.1 12.4 LNU261 27405.3 8.021 <0.2 27.3 LNU50 26023.3 6.821 <0.1 10.3 LNU33 25552.2 9.471 <0.05 50.3 LNU50 26025.3 7.624 <0.1 23.3 LNU33 25553.2 7.380 <0.4 17.1 LNU70 25311.4 7.590 <0.1 22.8 LNU33 25553.3 7.792 <0.2 23.7 LNU70 25313.2 6.816 <0.1 10.3 LNU33 25555.1 7.261 <0.4 15.2 LNU35 27421.2 8.163 <0.2 29.5 LNU35 27422.1 8.300 <0.05 31.7 LNU35 27423.3 11.263 <0.05 78.7 LNU35 27424.3 8.953 <0.05 42.1 LNU35 27424.4 8.455 <0.05 34.2 LNU50 26022.1 10.653 <0.05 69.1 LNU50 26023.2 12.657 <0.05 100.9 LNU50 26023.3 7.219 <0.5 14.6 LNU50 26024.1 7.889 <0.2 25.2 LNU50 26025.3 15.671 <0.05 148.7 LNU70 25311.4 14.371 <0.05 128.1 LNU70 25313.1 7.720 <0.1 22.5 LNU70 25313.2 10.792 <0.05 71.3 Table 64. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

TABLE 65 Genes showing improved root performance at nitrogen deficient conditions (T1 generation) Roots Length [cm] Roots Coverage [cm2] Gene Time p- % Gene Time p- % Name Point Ave. value incr. Name Point Ave. value incr. CONT. Roots 0.252 — 0.0 CONT. Roots 0.017 — 0.0 Length Coverage TP1 TP1 LNU107 Roots 0.477 0.000 89.1 LNU107 Roots 0.052 0.011 212.2 Length Coverage TP1 TP1 LNU118 Roots 0.338 0.000 33.8 LNU118 Roots 0.039 0.001 138.7 Length Coverage TP1 TP1 LNU121 Roots 0.492 0.004 95.1 LNU121 Roots 0.083 0.010 400.7 Length Coverage TP1 TP1 LNU141 Roots 0.435 0.020 72.4 LNU141 Roots 0.042 0.103 155.4 Length Coverage TP1 TP1 LNU150 Roots 0.355 0.024 40.5 LNU150 Roots 0.042 0.005 153.3 Length Coverage TP1 TP1 LNU154 Roots 0.439 0.001 74.0 LNU154 Roots 0.066 0.012 300.8 Length Coverage TP1 TP1 LNU210 Roots 0.401 0.001 59.0 LNU210 Roots 0.053 0.009 218.2 Length Coverage TP1 TP1 LNU68 Roots 0.403 0.038 59.7 LNU68 Roots 0.054 0.066 227.3 Length Coverage TP1 TP1 CONT. Roots 2.097 — 0.0 CONT. Roots 1.275 — 0.0 Length Coverage TP2 TP2 LNU107 Roots 2.164 0.741 3.2 LNU121 Roots 1.928 0.021 51.2 Length Coverage TP2 TP2 LNU121 Roots 2.638 0.033 25.8 LNU150 Roots 1.350 0.667 5.8 Length Coverage TP2 TP2 LNU150 Roots 2.296 0.318 9.5 LNU154 Roots 1.296 0.891 1.6 Length Coverage TP2 TP2 LNU154 Roots 2.493 0.015 18.9 LNU210 Roots 1.289 0.935 1.1 Length Coverage TP2 TP2 LNU210 Roots 2.280 0.244 8.7 LNU68 Roots 1.350 0.607 5.9 Length Coverage TP2 TP2 LNU68 Roots 2.524 0.010 20.4 CONT. Roots 3.537 — 0.0 Length Coverage TP2 TP3 CONT. Roots 4.072 — 0.0 LNU121 Roots 5.046 0.001 42.7 Length Coverage TP3 TP3 LNU121 Roots 4.586 0.100 12.6 LNU150 Roots 3.751 0.574 6.0 Length Coverage TP3 TP3 LNU154 Roots 4.448 0.335 9.2 LNU154 Roots 3.718 0.766 5.1 Length Coverage TP3 TP3 LNU210 Roots 4.153 0.766 2.0 CONT. Roots 0.045 — 0.0 Length Coverage TP3 TP1 LNU68 Roots 4.387 0.324 7.7 LNU127 Roots 0.119 0.184 164.9 Length Coverage TP3 TP1 CONT. Roots 0.324 — 0.0 LNU188 Roots 0.051 0.521 14.3 Length Coverage TP1 TP1 LNU127 Roots 0.561 0.073 73.0 LNU2 Roots 0.090 0.023 100.2 Length Coverage TP1 TP1 LNU188 Roots 0.423 0.046 30.3 LNU239 Roots 0.076 0.002 69.8 Length Coverage TP1 TP1 LNU2 Roots 0.518 0.002 59.7 LNU255 Roots 0.063 0.180 39.0 Length Coverage TP1 TP1 LNU239 Roots 0.512 0.000 57.7 LNU265 Roots 0.089 0.026 97.7 Length Coverage TP1 TP1 LNU255 Roots 0.496 0.005 53.0 LNU275 Roots 0.131 0.003 192.0 Length Coverage TP1 TP1 LNU265 Roots 0.455 0.003 40.4 LNU32 Roots 0.074 0.017 64.8 Length Coverage TP1 TP1 LNU275 Roots 0.552 0.000 70.0 LNU57 Roots 0.092 0.001 105.0 Length Coverage TP1 TP1 LNU32 Roots 0.525 0.162 61.7 LNU58 Roots 0.096 0.012 112.6 Length Coverage TP1 TP1 LNU57 Roots 0.493 0.000 51.9 LNU83 Roots 0.121 0.001 168.7 Length Coverage TP1 TP1 LNU58 Roots 0.509 0.001 56.8 CONT. Roots 1.456 — 0.0 Length Coverage TP1 TP2 LNU83 Roots 0.563 0.006 73.5 LNU127 Roots 1.703 0.344 16.9 Length Coverage TP1 TP2 CONT. Roots 2.393 — 0.0 LNU188 Roots 1.489 0.877 2.3 Length Coverage TP2 TP2 LNU127 Roots 2.701 0.092 12.9 LNU2 Roots 1.535 0.657 5.4 Length Coverage TP2 TP2 LNU265 Roots 2.427 0.804 1.4 LNU239 Roots 1.488 0.894 2.2 Length Coverage TP2 TP2 LNU275 Roots 2.955 0.012 23.5 LNU265 Roots 1.738 0.138 19.4 Length Coverage TP2 TP2 LNU57 Roots 2.718 0.057 13.6 LNU275 Roots 3.354 0.000 130.4 Length Coverage TP2 TP2 LNU58 Roots 2.980 0.007 24.6 LNU57 Roots 1.990 0.088 36.6 Length Coverage TP2 TP2 LNU83 Roots 2.943 0.041 23.0 LNU58 Roots 2.071 0.130 42.2 Length Coverage TP2 TP2 CONT. Roots 4.661 — 0.0 LNU83 Roots 2.185 0.081 50.1 Length Coverage TP3 TP2 LNU127 Roots 4.923 0.369 5.6 CONT. Roots 4.725 — 0.0 Length Coverage TP3 TP3 LNU217 Roots 4.893 0.607 5.0 LNU127 Roots 5.855 0.232 23.9 Length Coverage TP3 TP3 LNU265 Roots 4.843 0.629 3.9 LNU188 Roots 5.162 0.605 9.2 Length Coverage TP3 TP3 LNU275 Roots 5.711 0.030 22.5 LNU217 Roots 4.962 0.782 5.0 Length Coverage TP3 TP3 LNU57 Roots 5.252 0.111 12.7 LNU239 Roots 5.289 0.707 11.9 Length Coverage TP3 TP3 LNU58 Roots 6.931 0.000 48.7 LNU265 Roots 6.215 0.141 31.5 Length Coverage TP3 TP3 LNU83 Roots 5.573 0.047 19.6 LNU275 Roots 11.302 0.000 139.2 Length Coverage TP3 TP3 CONT. Roots 0.251 — 0.0 LNU32 Roots 5.220 0.272 10.5 Length Coverage TP1 TP3 LNU176 Roots 0.377 0.004 50.3 LNU57 Roots 5.808 0.095 22.9 Length Coverage TP1 TP3 LNU186 Roots 0.387 0.000 54.2 LNU58 Roots 11.015 0.002 133.1 Length Coverage TP1 TP3 LNU187 Roots 0.469 0.000 87.1 LNU83 Roots 6.154 0.195 30.2 Length Coverage TP1 TP3 LNU214 Roots 0.455 0.005 81.4 CONT. Roots 0.018 — 0.0 Length Coverage TP1 TP1 LNU223 Roots 0.422 0.000 68.4 LNU176 Roots 0.047 0.000 161.9 Length Coverage TP1 TP1 LNU233 Roots 0.416 0.000 66.1 LNU186 Roots 0.038 0.024 111.9 Length Coverage TP1 TP1 LNU245 Roots 0.432 0.000 72.3 LNU187 Roots 0.036 0.065 102.1 Length Coverage TP1 TP1 LNU247 Roots 0.391 0.049 56.0 LNU214 Roots 0.055 0.003 207.0 Length Coverage TP1 TP1 LNU251 Roots 0.483 0.026 92.8 LNU223 Roots 0.053 0.008 192.3 Length Coverage TP1 TP1 LNU284 Roots 0.302 0.089 20.5 LNU239 Roots 0.055 0.001 205.8 Length Coverage TP1 TP1 LNU289 Roots 0.541 0.000 115.9 LNU245 Roots 0.052 0.005 190.1 Length Coverage TP1 TP1 LNU70 Roots 0.346 0.027 38.0 LNU247 Roots 0.058 0.010 221.7 Length Coverage TP1 TP1 LNU85 Roots 0.515 0.001 105.6 LNU251 Roots 0.048 0.011 167.7 Length Coverage TP1 TP1 LNU86 Roots 0.432 0.000 72.3 LNU284 Roots 0.025 0.241 36.0 Length Coverage TP1 TP1 CONT. Roots 2.217 — 0.0 LNU289 Roots 0.064 0.000 253.0 Length Coverage TP2 TP1 LNU176 Roots 2.309 0.686 4.2 LNU70 Roots 0.042 0.010 132.3 Length Coverage TP2 TP1 LNU214 Roots 2.541 0.142 14.6 LNU85 Roots 0.067 0.000 273.2 Length Coverage TP2 TP1 LNU223 Roots 2.466 0.095 11.2 LNU86 Roots 0.066 0.005 266.8 Length Coverage TP2 TP1 LNU233 Roots 2.570 0.086 15.9 CONT. Roots 1.074 — 0.0 Length Coverage TP2 TP2 LNU245 Roots 2.500 0.087 12.7 LNU176 Roots 1.326 0.300 23.4 Length Coverage TP2 TP2 LNU247 Roots 2.725 0.109 22.9 LNU214 Roots 1.406 0.080 30.9 Length Coverage TP2 TP2 LNU251 Roots 2.349 0.343 5.9 LNU223 Roots 1.293 0.141 20.4 Length Coverage TP2 TP2 LNU284 Roots 2.335 0.488 5.3 LNU233 Roots 1.428 0.093 32.9 Length Coverage TP2 TP2 LNU289 Roots 2.995 0.000 35.1 LNU245 Roots 1.265 0.125 17.8 Length Coverage TP2 TP2 LNU70 Roots 2.416 0.313 9.0 LNU247 Roots 1.536 0.005 43.0 Length Coverage TP2 TP2 LNU85 Roots 2.854 0.059 28.7 LNU284 Roots 1.377 0.377 28.2 Length Coverage TP2 TP2 LNU86 Roots 2.359 0.242 6.4 LNU289 Roots 1.643 0.001 53.0 Length Coverage TP2 TP2 CONT. Roots 3.944 — 0.0 LNU70 Roots 1.242 0.329 15.6 Length Coverage TP3 TP2 LNU176 Roots 4.150 0.692 5.2 LNU85 Roots 1.648 0.094 53.4 Length Coverage TP3 TP2 LNU214 Roots 4.160 0.286 5.5 LNU86 Roots 1.180 0.402 9.9 Length Coverage TP3 TP2 LNU223 Roots 4.286 0.266 8.7 CONT. Roots 3.404 — 0.0 Length Coverage TP3 TP3 LNU233 Roots 4.303 0.429 9.1 LNU176 Roots 3.971 0.527 16.7 Length Coverage TP3 TP3 LNU245 Roots 4.127 0.664 4.6 LNU214 Roots 4.249 0.169 24.9 Length Coverage TP3 TP3 LNU247 Roots 4.561 0.249 15.7 LNU223 Roots 3.730 0.596 9.6 Length Coverage TP3 TP3 LNU251 Roots 3.996 0.778 1.3 LNU233 Roots 4.290 0.194 26.0 Length Coverage TP3 TP3 LNU289 Roots 4.422 0.344 12.1 LNU245 Roots 3.652 0.665 7.3 Length Coverage TP3 TP3 LNU70 Roots 4.245 0.393 7.6 LNU247 Roots 5.428 0.035 59.5 Length Coverage TP3 TP3 LNU85 Roots 4.550 0.343 15.4 LNU284 Roots 4.593 0.294 34.9 Length Coverage TP3 TP3 CONT. Roots 0.787 — 0.0 LNU289 Roots 4.654 0.209 36.7 Length Coverage TP1 TP3 LNU105 Roots 0.875 0.213 11.2 LNU70 Roots 3.701 0.708 8.7 Length Coverage TP1 TP3 LNU123 Roots 0.837 0.514 6.3 LNU85 Roots 4.066 0.532 19.5 Length Coverage TP1 TP3 LNU13 Roots 0.795 0.911 0.9 CONT. Roots 0.233 — 0.0 Length Coverage TP1 TP1 LNU134 Roots 0.871 0.124 10.6 LNU105 Roots 0.261 0.329 12.1 Length Coverage TP1 TP1 LNU190 Roots 0.821 0.614 4.3 LNU123 Roots 0.238 0.912 1.9 Length Coverage TP1 TP1 LNU198 Roots 0.819 0.606 4.1 LNU134 Roots 0.284 0.151 21.8 Length Coverage TP1 TP1 LNU200 Roots 1.049 0.020 33.3 LNU190 Roots 0.262 0.395 12.5 Length Coverage TP1 TP1 CONT. Roots 3.113 — 0.0 LNU198 Roots 0.257 0.466 10.4 Length Coverage TP2 TP1 LNU105 Roots 3.270 0.198 5.1 LNU200 Roots 0.348 0.006 49.4 Length Coverage TP2 TP1 LNU134 Roots 3.134 0.799 0.7 CONT. Roots 2.289 — 0.0 Length Coverage TP2 TP2 LNU190 Roots 3.121 0.943 0.3 LNU198 Roots 2.307 0.891 0.8 Length Coverage TP2 TP2 LNU198 Roots 3.190 0.558 2.5 LNU200 Roots 2.426 0.708 6.0 Length Coverage TP2 TP2 LNU200 Roots 3.511 0.295 12.8 CONT. Roots 0.029 — 0.0 Length Coverage TP2 TP1 CONT. Roots 0.308 — 0.0 LNU243 Roots 0.071 0.210 146.6 Length Coverage TP1 TP1 LNU243 Roots 0.507 0.184 64.4 LNU244 Roots 0.049 0.147 70.0 Length Coverage TP1 TP1 LNU244 Roots 0.481 0.061 55.9 LNU262 Roots 0.049 0.097 71.8 Length Coverage TP1 TP1 LNU262 Roots 0.432 0.048 40.2 LNU29 Roots 0.047 0.117 62.4 Length Coverage TP1 TP1 LNU29 Roots 0.406 0.242 31.7 LNU51 Roots 0.095 0.003 228.5 Length Coverage TP1 TP1 LNU51 Roots 0.610 0.003 98.0 LNU60 Roots 0.043 0.351 48.4 Length Coverage TP1 TP1 LNU60 Roots 0.330 0.681 6.9 CONT. Roots 1.681 — 0.0 Length Coverage TP1 TP2 CONT. Roots 2.538 — 0.0 LNU225 Roots 1.688 0.972 0.4 Length Coverage TP2 TP2 LNU243 Roots 2.561 0.935 0.9 LNU262 Roots 1.827 0.531 8.7 Length Coverage TP2 TP2 LNU262 Roots 2.725 0.293 7.4 LNU51 Roots 1.934 0.479 15.1 Length Coverage TP2 TP2 LNU29 Roots 2.690 0.470 6.0 LNU60 Roots 2.225 0.191 32.3 Length Coverage TP2 TP2 LNU51 Roots 3.044 0.220 19.9 CONT. Roots 4.355 — 0.0 Length Coverage TP2 TP3 LNU60 Roots 2.872 0.149 13.2 LNU225 Roots 5.308 0.168 21.9 Length Coverage TP2 TP3 CONT. Roots_ 4.714 — 0.0 LNU243 Roots 4.393 0.935 0.9 Length_ Coverage TP3 TP3 LNU51 Roots_ 4.998 0.709 6.0 LNU262 Roots 4.744 0.431 8.9 Length_ Coverage TP3 TP3 LNU60 Roots_ 5.050 0.471 7.1 LNU266 Roots 4.867 0.449 11.8 Length_ Coverage TP3 TP3 LNU29 Roots 4.473 0.781 2.7 Coverage TP3 LNU51 Roots 4.551 0.792 4.5 Coverage TP3 LNU60 Roots 6.276 0.084 44.1 Coverage TP3 Table 65. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

The genes listed in Tables 66, 67, 68 and 69 have improved plant growth rate (growth rate of the leaf area, root coverage and root length) when grown under limiting nitrogen growth conditions, compared to control plants. Plants showing fast growth rate show a better plant establishment in soil under nitrogen deficient conditions. Faster growth was observed when growth rate of leaf area and root length and coverage was measured. The genes were cloned under the regulation of a constitutive promoter (At6669) or root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one tissue culture assay and the results obtained where positive as well. Event with p-value <0.1 was considered statistically significant.

TABLE 66 Genes showing improved plant growth rate at nitrogen deficient conditions (T2 generation) RGR Of Roots RGR Of Leaf Area Coverage Gene Event p- % Gene Event p- % Name # Ave. value incr. Name # Ave. value incr. CONT. — 0.055 — 0.0 CONT. — 0.728 — 0.0 LNU100 14474.3 0.088 0.002 60.1 LNU100 14474.3 1.190 0.000 63.4 LNU100 14473.1 0.065 0.103 18.6 LNU100 14473.1 0.840 0.202 15.4 LNU104 25033.3 0.077 0.004 39.3 LNU100 14471.4 0.837 0.160 15.0 LNU104 25034.1 0.072 0.038 31.5 LNU104 25033.3 0.891 0.075 22.4 LNU213 24654.4 0.096 0.005 73.8 LNU104 25034.1 0.762 0.650 4.7 LNU213 24653.2 0.086 0.000 55.7 LNU213 24653.2 1.117 0.000 53.4 LNU213 24651.1 0.060 0.464 8.2 LNU213 24654.4 1.027 0.051 41.1 LNU218 24783.2 0.076 0.044 37.9 LNU213 24653.1 0.837 0.214 14.9 LNU218 24781.7 0.075 0.070 35.8 LNU213 24651.1 0.760 0.628 4.4 LNU4 25134.2 0.081 0.001 47.6 LNU218 24783.2 1.061 0.012 45.7 LNU4 25134.1 0.065 0.267 17.5 LNU218 24781.7 0.814 0.498 11.9 LNU48 24802.2 0.089 0.001 61.2 LNU4 25134.2 0.965 0.013 32.6 LNU48 24803.2 0.071 0.019 28.6 LNU4 25134.1 0.832 0.252 14.2 LNU48 24804.4 0.070 0.060 27.8 LNU4 25131.1 0.762 0.625 4.7 LNU8 25063.1 0.091 0.000 65.8 LNU48 24802.2 1.237 0.000 69.9 LNU8 25063.6 0.080 0.076 44.7 LNU48 24804.4 1.063 0.001 46.0 LNU94 24833.3 0.074 0.023 34.5 LNU48 24802.1 0.776 0.586 6.6 LNU94 24834.1 0.063 0.392 14.3 LNU48 24803.2 0.771 0.607 5.9 LNU94 24834.4 0.062 0.403 13.4 LNU8 25063.1 1.435 0.000 97.1 CONT. — 0.081 — 0.0 LNU8 25063.6 0.933 0.267 28.1 LNU1 24681.3 0.104 0.206 28.0 LNU94 24833.3 0.922 0.042 26.6 LNU1 24682.1 0.097 0.321 19.8 LNU94 24834.4 0.805 0.441 10.6 LNU1 24684.1 0.097 0.296 19.3 CONT. — 0.887 — 0.0 LNU1 24681.1 0.095 0.370 17.0 LNU1 24682.2 1.298 0.113 46.3 LNU1 24682.2 0.092 0.542 12.9 LNU1 24684.1 1.291 0.000 45.5 LNU133 24744.3 0.114 0.079 40.6 LNU1 24681.1 1.248 0.019 40.6 LNU133 24741.1 0.105 0.096 29.6 LNU1 24681.3 1.092 0.095 23.1 LNU133 24744.2 0.087 0.712 6.9 LNU1 24682.1 0.989 0.258 11.5 LNU175 24732.4 0.129 0.022 59.1 LNU133 24744.3 1.638 0.001 84.6 LNU175 24732.1 0.124 0.007 53.3 LNU133 24741.1 1.461 0.000 64.7 LNU175 24734.4 0.095 0.350 17.4 LNU133 24741.2 1.071 0.021 20.7 LNU175 24731.2 0.087 0.712 7.0 LNU133 24744.2 1.049 0.150 18.3 LNU178 14614.5 0.115 0.078 41.9 LNU133 24742.2 1.020 0.263 14.9 LNU178 14611.5 0.106 0.129 30.8 LNU175 24732.4 1.929 0.002 117.4 LNU178 14612.1 0.089 0.587 9.5 LNU175 24732.1 1.756 0.000 97.9 LNU178 14611.1 0.085 0.782 5.0 LNU175 24734.4 1.182 0.014 33.3 LNU215 24664.3 0.113 0.068 39.1 LNU175 24731.2 1.070 0.115 20.6 LNU215 24661.4 0.087 0.711 6.9 LNU175 24733.4 1.019 0.271 14.9 LNU24 24973.1 0.104 0.160 28.2 LNU178 14611.5 1.630 0.000 83.7 LNU24 24971.2 0.101 0.203 24.2 LNU178 14611.1 1.245 0.035 40.3 LNU24 24971.4 0.100 0.374 23.4 LNU178 14614.5 1.219 0.066 37.4 LNU6 24992.2 0.106 0.084 31.0 LNU178 14612.1 1.002 0.265 13.0 LNU6 24994.1 0.092 0.476 13.4 LNU178 14611.4 0.985 0.237 11.0 LNU6 24993.3 0.089 0.601 10.2 LNU215 24664.3 1.409 0.003 58.8 LNU6 24994.2 0.088 0.658 8.3 LNU215 24661.4 1.132 0.043 27.6 LNU82 24823.1 0.095 0.328 17.5 LNU215 24664.2 1.100 0.015 24.0 LNU82 24824.1 0.086 0.758 6.3 LNU215 24663.4 1.034 0.121 16.5 LNU9 25003.1 0.093 0.468 14.8 LNU24 24973.1 1.501 0.000 69.2 LNU9 25001.2 0.089 0.598 10.1 LNU24 24971.4 1.350 0.001 52.2 CONT. — 0.058 — 0.0 LNU24 24971.2 1.271 0.001 43.3 LNU120 25463.7 0.081 0.001 39.9 LNU24 24971.3 0.965 0.419 8.8 LNU120 25463.3 0.074 0.019 27.4 LNU24 24972.1 0.952 0.578 7.3 LNU124 14501.7 0.079 0.007 36.5 LNU6 24992.3 1.524 0.001 71.8 LNU124 14502.7 0.068 0.125 17.3 LNU6 24994.2 1.176 0.024 32.5 LNU124 14501.1 0.065 0.277 12.6 LNU6 24994.5 1.067 0.264 20.3 LNU132 14102.9 0.066 0.251 14.0 LNU6 24993.3 1.045 0.147 17.8 LNU132 14102.7 0.064 0.379 10.6 LNU6 24994.1 1.012 0.332 14.1 LNU140 14112.7 0.097 0.000 67.6 LNU82 24823.1 1.167 0.036 31.5 LNU140 14111.6 0.070 0.081 21.0 LNU82 24824.2 1.126 0.036 27.0 LNU140 14114.8 0.063 0.435 8.5 LNU82 24824.3 0.979 0.370 10.4 LNU140 14112.6 0.060 0.732 3.8 LNU82 24824.1 0.978 0.555 10.2 LNU180 24724.3 0.099 0.000 71.3 LNU9 25001.1 1.294 0.001 45.8 LNU180 24723.3 0.080 0.009 37.5 LNU9 25003.1 1.232 0.023 38.9 LNU196 25534.1 0.069 0.171 18.6 LNU9 25001.2 1.118 0.135 26.0 LNU196 25533.1 0.066 0.349 14.2 LNU9 25001.3 1.117 0.041 25.9 LNU20 24932.4 0.068 0.174 17.3 CONT. — 0.908 — 0.0 LNU20 24933.2 0.065 0.390 12.7 LNU120 25463.7 1.427 0.000 57.3 LNU36 25562.3 0.085 0.024 46.0 LNU120 25463.3 1.010 0.346 11.3 LNU71 25853.4 0.087 0.001 50.3 LNU124 14502.1 1.162 0.095 28.1 LNU71 25852.4 0.060 0.773 3.2 LNU124 14501.7 1.135 0.152 25.0 CONT. — 0.060 — 0.0 LNU124 14502.7 1.003 0.415 10.6 LNU1 24681.3 0.073 0.306 20.5 LNU124 14501.1 0.960 0.683 5.8 LNU110 24952.3 0.090 0.013 48.7 LNU132 14102.7 1.130 0.095 24.5 LNU110 24953.3 0.079 0.110 30.2 LNU132 14102.9 1.129 0.060 24.4 LNU110 24953.2 0.069 0.323 14.0 LNU140 14112.7 1.571 0.000 73.0 LNU175 24732.2 0.087 0.008 44.2 LNU140 14111.6 1.145 0.048 26.2 LNU175 24733.4 0.070 0.218 16.4 LNU140 14112.6 0.970 0.554 6.9 LNU19 25151.1 0.090 0.001 48.9 LNU140 14114.8 0.966 0.603 6.5 LNU19 25153.3 0.079 0.063 31.5 LNU180 24724.3 1.590 0.000 75.2 LNU215 24664.2 0.091 0.000 50.8 LNU180 24723.3 1.265 0.004 39.4 LNU215 24663.4 0.078 0.016 28.4 LNU180 24721.4 0.942 0.765 3.8 LNU215 24663.3 0.071 0.182 17.5 LNU20 24932.4 1.177 0.028 29.7 LNU215 24661.4 0.065 0.558 7.1 LNU20 24933.2 1.021 0.453 12.5 LNU27 24873.1 0.088 0.012 45.4 LNU36 25562.3 1.375 0.017 51.5 LNU27 24873.4 0.080 0.048 32.1 LNU36 25562.4 1.090 0.208 20.1 LNU27 24872.4 0.067 0.357 11.3 LNU71 25853.4 1.170 0.066 29.0 LNU44 24924.3 0.112 0.001 84.9 CONT. — 0.869 — 0.0 LNU44 24924.2 0.089 0.004 48.1 LNU1 24682.1 0.948 0.453 9.2 LNU44 24922.3 0.076 0.072 25.2 LNU110 24952.3 1.151 0.199 32.5 LNU54 24903.5 0.102 0.000 69.7 LNU110 24953.2 0.948 0.500 9.1 LNU54 24901.2 0.097 0.005 60.2 LNU175 24732.2 1.291 0.013 48.7 LNU54 24903.3 0.078 0.058 29.8 LNU175 24732.1 1.018 0.248 17.2 LNU79 24884.4 0.102 0.000 68.5 LNU175 24734.4 0.927 0.633 6.7 LNU79 24881.1 0.088 0.003 46.2 LNU19 25151.1 1.046 0.194 20.4 LNU79 24884.3 0.077 0.045 27.7 LNU215 24664.2 1.315 0.001 51.4 LNU79 24882.2 0.068 0.280 13.4 LNU215 24663.4 1.179 0.010 35.8 CONT. — 0.078 — 0.0 LNU215 24663.3 1.033 0.208 19.0 LNU109 24891.5 0.105 0.016 35.4 LNU215 24661.4 1.030 0.127 18.6 LNU109 24892.5 0.097 0.142 24.5 LNU215 24663.1 0.907 0.688 4.5 LNU109 24892.6 0.095 0.219 21.5 LNU27 24873.1 1.325 0.016 52.6 LNU109 24891.2 0.088 0.462 12.6 LNU27 24873.4 1.072 0.138 23.5 LNU110 24952.1 0.155 0.000 99.4 LNU44 24924.2 1.395 0.002 60.7 LNU110 24952.3 0.111 0.031 42.2 LNU44 24924.3 1.315 0.018 51.4 LNU110 24953.2 0.106 0.030 36.6 LNU44 24922.3 1.296 0.044 49.2 LNU133 24744.3 0.121 0.000 55.2 LNU44 24923.3 1.123 0.025 29.3 LNU133 24741.1 0.103 0.017 32.5 LNU54 24903.5 1.573 0.000 81.2 LNU133 24741.2 0.097 0.033 25.0 LNU54 24901.2 1.405 0.015 61.7 LNU133 24744.2 0.088 0.329 13.5 LNU54 24903.3 1.367 0.008 57.3 LNU133 24742.2 0.083 0.581 6.3 LNU54 24902.4 1.137 0.031 30.9 LNU19 25151.1 0.106 0.007 36.3 LNU79 24881.1 1.407 0.001 62.0 LNU27 24873.4 0.125 0.000 60.1 LNU79 24884.4 1.407 0.000 61.9 LNU44 24922.3 0.113 0.000 44.6 LNU79 24884.3 1.127 0.095 29.8 LNU44 24924.3 0.091 0.308 17.0 LNU79 24882.2 1.053 0.073 21.2 LNU44 24923.1 0.085 0.518 8.7 LNU79 24883.2 0.899 0.782 3.5 LNU54 24901.2 0.119 0.000 52.2 CONT. — 1.054 — 0.0 LNU54 24903.5 0.104 0.031 33.2 LNU109 24891.5 1.313 0.018 24.6 LNU54 24902.4 0.094 0.056 20.3 LNU109 24892.6 1.256 0.186 19.1 LNU6 24994.5 0.112 0.005 43.2 LNU110 24952.1 2.265 0.000 114.9 LNU6 24992.3 0.107 0.012 36.7 LNU110 24952.3 1.456 0.012 38.1 LNU79 24884.4 0.120 0.000 54.1 LNU110 24953.2 1.221 0.308 15.8 LNU79 24881.1 0.107 0.012 36.9 LNU110 24954.3 1.163 0.333 10.4 LNU79 24882.2 0.098 0.056 26.4 LNU133 24744.3 1.717 0.000 62.9 LNU79 24884.3 0.092 0.228 18.2 LNU133 24741.1 1.470 0.026 39.5 CONT. — 0.052 — 0.0 LNU133 24742.2 1.203 0.166 14.2 LNU109 24892.8 0.104 0.000 101.5 LNU133 24741.2 1.123 0.527 6.5 LNU109 24891.2 0.104 0.002 100.4 LNU19 25151.1 1.490 0.008 41.3 LNU109 24891.5 0.072 0.136 38.7 LNU27 24873.4 1.673 0.000 58.7 LNU109 24892.5 0.060 0.394 15.2 LNU44 24922.3 1.944 0.000 84.4 LNU143 25975.3 0.081 0.021 56.0 LNU54 24901.2 1.669 0.000 58.4 LNU143 25972.1 0.074 0.032 42.5 LNU54 24903.5 1.243 0.185 18.0 LNU143 25975.2 0.069 0.088 34.3 LNU6 24992.3 1.678 0.001 59.2 LNU143 25971.5 0.066 0.085 26.9 LNU6 24994.5 1.323 0.144 25.5 LNU143 25971.2 0.060 0.346 16.5 LNU6 24994.2 1.157 0.317 9.7 LNU154 14604.7 0.092 0.002 78.6 LNU79 24884.4 1.756 0.000 66.6 LNU154 14604.6 0.086 0.006 66.7 LNU79 24881.1 1.355 0.008 28.6 LNU154 14601.6 0.077 0.098 48.3 LNU79 24882.2 1.263 0.206 19.8 LNU154 14602.8 0.069 0.185 34.0 LNU79 24884.3 1.223 0.225 16.1 LNU154 14604.4 0.069 0.082 33.4 LNU79 24883.2 1.101 0.613 4.5 LNU196 25532.2 0.113 0.000 117.6 CONT. — 0.737 — 0.0 LNU196 25534.1 0.089 0.017 71.3 LNU109 24892.8 1.439 0.000 95.2 LNU196 25531.2 0.073 0.034 40.4 LNU109 24891.2 1.093 0.066 48.3 LNU196 25532.1 0.065 0.357 25.8 LNU109 24891.5 1.071 0.028 45.2 LNU207 24642.5 0.094 0.001 82.1 LNU143 25975.3 1.056 0.012 43.2 LNU207 24642.4 0.094 0.001 81.0 LNU143 25972.1 0.980 0.035 32.9 LNU207 24644.18 0.080 0.006 54.8 LNU143 25975.2 0.917 0.233 24.3 LNU207 24641.1 0.056 0.655 7.3 LNU143 25971.5 0.877 0.338 19.0 LNU207 24644.13 0.055 0.786 5.7 LNU154 14604.6 1.099 0.009 49.0 LNU288 14562.12 0.075 0.048 44.1 LNU154 14601.6 1.081 0.079 46.6 LNU288 14562.7 0.075 0.022 44.1 LNU154 14604.7 1.015 0.024 37.7 LNU288 14562.1 0.069 0.154 32.5 LNU154 14602.8 0.982 0.253 33.2 LNU288 14564.9 0.066 0.089 27.6 LNU196 25532.2 1.650 0.000 123.9 LNU288 14562.9 0.064 0.261 23.7 LNU196 25534.1 1.327 0.052 80.0 LNU50 26024.2 0.085 0.007 64.1 LNU196 25532.1 0.971 0.248 31.7 LNU50 26023.2 0.073 0.028 40.6 LNU196 25531.2 0.817 0.525 10.8 LNU50 26025.4 0.065 0.125 26.0 LNU196 25533.1 0.783 0.607 6.2 LNU50 26022.1 0.062 0.321 19.8 LNU207 24642.4 1.393 0.010 89.0 LNU50 26023.5 0.056 0.558 9.1 LNU207 24642.5 1.164 0.002 57.9 LNU52 25723.2 0.126 0.000 143.1 LNU207 24644.18 1.102 0.010 49.5 LNU52 25721.4 0.094 0.034 81.1 LNU207 24644.13 0.920 0.279 24.8 LNU52 25721.3 0.086 0.008 66.2 LNU288 14562.1 1.018 0.124 38.1 CONT. — 0.064 — 0.0 LNU288 14562.7 0.987 0.056 33.9 LNU143 25975.2 0.075 0.257 15.9 LNU288 14564.9 0.939 0.037 27.3 LNU154 14602.8 0.079 0.120 22.7 LNU288 14562.12 0.823 0.473 11.7 LNU154 14604.4 0.070 0.618 8.3 LNU288 14562.9 0.823 0.387 11.7 LNU207 24642.5 0.092 0.008 43.2 LNU50 26023.2 1.105 0.011 49.9 LNU207 24641.1 0.079 0.154 22.6 LNU50 26024.2 1.085 0.063 47.2 LNU207 24642.4 0.069 0.560 7.5 LNU50 26025.4 0.978 0.038 32.6 LNU211 24774.4 0.271 0.173 321.2 LNU50 26023.5 0.855 0.264 16.0 LNU52 25721.1 0.091 0.013 42.2 LNU50 26022.1 0.810 0.542 9.9 LNU52 25723.2 0.085 0.074 31.7 LNU52 25723.2 1.741 0.000 136.1 LNU52 25723.1 0.081 0.191 25.5 LNU52 25721.4 1.195 0.045 62.1 LNU52 25721.2 0.073 0.369 13.7 LNU52 25721.3 1.193 0.024 61.8 LNU69 14571.1 0.081 0.108 26.1 LNU52 25723.1 0.805 0.623 9.2 LNU69 14572.9 0.079 0.197 23.1 CONT. — 1.006 — 0.0 LNU69 14572.8 0.074 0.362 14.4 LNU143 25975.2 1.194 0.208 18.7 CONT. — 0.072 — 0.0 LNU143 25975.3 1.085 0.620 7.8 LNU150 24842.9 0.115 0.006 60.7 LNU154 14602.8 1.225 0.116 21.7 LNU150 24841.9 0.082 0.477 15.1 LNU207 24642.5 1.333 0.028 32.4 LNU179 24632.5 0.097 0.103 35.0 LNU207 24641.1 1.265 0.082 25.7 LNU179 24631.9 0.084 0.441 16.8 LNU207 24642.4 1.159 0.228 15.2 LNU232 26003.7 0.083 0.456 15.9 LNU211 24771.1 1.136 0.330 12.9 LNU235 26184.4 0.101 0.063 40.9 LNU52 25721.1 1.458 0.019 44.8 LNU235 26185.3 0.100 0.080 40.3 LNU52 25723.1 1.362 0.084 35.4 LNU242 25473.1 0.096 0.109 33.9 LNU52 25721.2 1.328 0.093 32.0 LNU242 25474.1 0.079 0.639 9.9 LNU52 25723.2 1.208 0.271 20.1 LNU242 25471.1 0.079 0.638 9.8 LNU69 14571.1 1.398 0.027 38.9 LNU76 26423.1 0.097 0.093 35.9 LNU69 14572.9 1.140 0.342 13.2 LNU76 26421.2 0.089 0.241 24.9 LNU69 14572.8 1.105 0.378 9.8 LNU76 26425.1 0.086 0.377 19.5 CONT. — 0.860 — 0.0 LNU76 26421.1 0.077 0.746 7.3 LNU150 24842.9 1.560 0.001 81.4 LNU95 13985.11 0.101 0.055 40.8 LNU150 24841.9 1.169 0.141 36.0 LNU95 13985.15 0.079 0.623 10.3 LNU150 24843.5 1.141 0.199 32.7 LNU95 13985.12 0.076 0.784 5.9 LNU179 24632.5 1.501 0.005 74.5 CONT. — 0.067 — 0.0 LNU179 24631.9 1.269 0.062 47.5 LNU118 14013.6 0.078 0.267 16.4 LNU179 24631.6 0.933 0.723 8.5 LNU118 14012.15 0.076 0.371 12.9 LNU232 26003.7 1.110 0.227 29.1 LNU150 24841.6 0.077 0.375 13.8 LNU235 26184.4 1.576 0.001 83.3 LNU150 24841.9 0.075 0.470 11.0 LNU235 26185.3 1.416 0.013 64.7 LNU150 24842.9 0.072 0.666 7.1 LNU235 26182.1 1.048 0.361 21.8 LNU179 24631.6 0.079 0.251 17.0 LNU235 26184.2 1.019 0.431 18.5 LNU179 24631.7 0.078 0.279 15.7 LNU242 25473.1 1.482 0.004 72.3 LNU179 24632.7 0.072 0.601 7.2 LNU242 25474.1 1.275 0.056 48.3 LNU232 26001.5 0.082 0.155 21.2 LNU76 26425.1 1.342 0.026 56.1 LNU232 26003.3 0.070 0.741 4.7 LNU76 26421.2 1.194 0.112 38.8 LNU235 26184.4 0.115 0.000 71.6 LNU76 26423.1 1.177 0.128 36.9 LNU235 26185.2 0.113 0.000 68.3 LNU76 26421.1 1.021 0.471 18.7 LNU235 26184.2 0.094 0.007 39.9 LNU95 13985.11 1.522 0.003 76.9 LNU235 26182.1 0.071 0.718 5.1 LNU95 13985.15 1.128 0.194 31.2 LNU242 25474.1 0.098 0.004 45.3 LNU95 13985.19 1.100 0.280 27.9 LNU288 14563.9 0.096 0.006 43.3 LNU95 13985.12 1.090 0.273 26.8 LNU288 14562.1 0.090 0.024 33.5 LNU95 13985.16 0.947 0.670 10.1 LNU288 14562.7 0.081 0.183 20.1 CONT. — 1.017 — 0.0 LNU288 14564.9 0.080 0.203 18.5 LNU232 26001.5 1.259 0.085 23.7 LNU76 26421.2 0.090 0.068 33.6 LNU235 26184.4 1.645 0.000 61.7 LNU76 26422.2 0.086 0.063 28.3 LNU235 26185.2 1.636 0.000 60.8 LNU76 26423.1 0.086 0.099 27.9 LNU235 26184.2 1.205 0.181 18.4 LNU95 13985.16 0.126 0.000 87.0 LNU242 25474.1 1.210 0.179 19.0 LNU95 13985.15 0.113 0.000 68.6 LNU288 14563.9 1.512 0.002 48.6 LNU95 13985.12 0.092 0.013 36.2 LNU288 14562.1 1.225 0.102 20.4 CONT. — 0.066 — 0.0 LNU288 14564.9 1.119 0.472 10.0 LNU101 27632.7 0.080 0.040 21.0 LNU288 14562.7 1.065 0.698 4.7 LNU128 26515.3 0.087 0.003 30.2 LNU76 26421.2 1.389 0.037 36.6 LNU192 28315.2 0.085 0.007 27.6 LNU76 26423.1 1.131 0.435 11.1 LNU192 28313.2 0.070 0.605 5.1 LNU76 26422.2 1.123 0.483 10.4 LNU206 27621.2 0.077 0.140 15.4 LNU95 13985.16 1.594 0.000 56.7 LNU211 24771.1 0.073 0.298 10.1 LNU95 13985.12 1.420 0.014 39.6 LNU211 24773.2 0.071 0.480 7.1 LNU95 13985.15 1.417 0.004 39.3 LNU282 27563.3 0.082 0.030 22.7 CONT. — 0.870 — 0.0 LNU282 27563.1 0.078 0.103 17.4 LNU101 27632.7 1.210 0.000 39.0 LNU282 27562.1 0.075 0.286 12.5 LNU101 27632.1 0.985 0.153 13.2 LNU69 14571.1 0.089 0.001 33.3 LNU101 27635.1 0.976 0.280 12.1 LNU75 27572.2 0.072 0.395 8.8 LNU128 26515.3 1.467 0.000 68.5 LNU75 27572.1 0.072 0.379 8.5 LNU128 26511.5 1.191 0.000 36.8 CONT. — 0.056 — 0.0 LNU128 26515.2 1.071 0.024 23.0 LNU118 14012.15 0.059 0.772 3.7 LNU128 26511.4 0.891 0.790 2.4 LNU206 27621.2 0.097 0.018 72.5 LNU192 28315.2 1.393 0.000 60.0 LNU206 27621.1 0.085 0.007 50.7 LNU192 28313.2 1.211 0.000 39.2 LNU206 27622.1 0.077 0.021 37.3 LNU192 28313.3 1.079 0.026 23.9 LNU206 27622.4 0.073 0.068 29.9 LNU192 28312.2 0.927 0.454 6.5 LNU249 26153.1 0.084 0.003 48.8 LNU206 27621.2 1.252 0.000 43.9 LNU249 26154.2 0.071 0.081 26.7 LNU206 27621.1 1.059 0.023 21.6 LNU249 26152.4 0.060 0.659 6.4 LNU206 27622.1 0.985 0.140 13.2 LNU282 27563.1 0.076 0.016 34.7 LNU211 24771.1 1.374 0.000 57.8 LNU282 27565.2 0.075 0.051 33.1 LNU211 24773.2 1.127 0.006 29.5 LNU288 14564.8 0.087 0.001 55.1 LNU282 27562.1 1.477 0.000 69.7 LNU288 14563.9 0.082 0.000 46.0 LNU282 27563.3 1.333 0.000 53.2 LNU288 14562.9 0.070 0.066 25.0 LNU282 27563.1 1.262 0.000 45.0 LNU288 14563.6 0.065 0.305 14.8 LNU282 27565.2 0.966 0.204 11.0 LNU288 14562.7 0.060 0.678 5.9 LNU69 14571.1 1.528 0.000 75.6 LNU75 27572.3 0.094 0.000 67.3 LNU69 14573.5 1.115 0.004 28.2 LNU75 27572.2 0.081 0.019 43.6 LNU69 14572.9 0.895 0.798 2.9 LNU75 27571.2 0.081 0.004 43.3 LNU75 27572.2 1.373 0.000 57.8 LNU75 27571.4 0.079 0.005 40.0 LNU75 27572.1 1.152 0.001 32.4 CONT. — 0.076 — 0.0 LNU75 27572.3 1.006 0.148 15.6 LNU112 28212.4 0.082 0.565 7.8 LNU75 27571.4 0.957 0.334 9.9 LNU14 27823.2 0.083 0.490 9.5 CONT. — 0.804 — 0.0 LNU183 24863.1 0.098 0.030 29.7 LNU101 27632.5 0.982 0.112 22.2 LNU183 24863.12 0.091 0.130 20.4 LNU118 14012.15 1.037 0.038 29.1 LNU183 24864.6 0.085 0.487 12.6 LNU118 14012.12 0.843 0.692 4.9 LNU183 24865.1 0.080 0.652 6.2 LNU206 27621.2 1.502 0.000 86.9 LNU201 28223.1 0.084 0.410 11.6 LNU206 27622.4 1.352 0.000 68.3 LNU201 28222.2 0.078 0.792 3.6 LNU206 27622.1 1.218 0.004 51.5 LNU268 26044.2 0.083 0.520 9.7 LNU206 27621.1 1.124 0.018 39.9 CONT. — 0.066 — 0.0 LNU249 26153.1 1.209 0.007 50.5 LNU11 28205.1 0.089 0.021 34.1 LNU249 26154.2 1.142 0.032 42.0 LNU11 28205.2 0.075 0.357 12.2 LNU249 26152.4 1.042 0.075 29.6 LNU11 28204.1 0.074 0.414 11.5 LNU249 26151.1 0.841 0.753 4.7 LNU11 28203.2 0.072 0.539 7.7 LNU282 27563.1 1.273 0.001 58.4 LNU112 28212.4 0.081 0.105 22.1 LNU282 27565.2 1.273 0.002 58.4 LNU112 28212.1 0.078 0.181 17.6 LNU282 27562.1 0.836 0.765 4.0 LNU112 28212.3 0.076 0.356 14.5 LNU288 14563.9 1.420 0.000 76.7 LNU14 27821.3 0.091 0.009 36.3 LNU288 14563.6 1.166 0.018 45.1 LNU14 27821.4 0.080 0.139 21.0 LNU288 14564.8 1.158 0.007 44.1 LNU14 27824.2 0.073 0.440 10.6 LNU288 14562.9 1.104 0.004 37.3 LNU183 24864.6 0.108 0.000 63.2 LNU288 14562.7 1.029 0.064 28.1 LNU183 24863.12 0.099 0.001 49.5 LNU75 27572.2 1.648 0.000 105.0 LNU183 24865.1 0.095 0.009 42.5 LNU75 27571.2 1.413 0.000 75.8 LNU183 24863.1 0.089 0.012 34.3 LNU75 27572.3 1.342 0.000 67.0 LNU191 28325.4 0.081 0.112 21.4 LNU75 27571.4 1.151 0.007 43.2 LNU191 28324.2 0.078 0.228 17.5 CONT. — 1.337 — 0.0 LNU191 28321.3 0.073 0.438 10.2 LNU112 28212.4 1.471 0.446 10.0 LNU191 28323.1 0.073 0.468 9.9 LNU183 24865.1 1.454 0.553 8.7 LNU201 28222.2 0.097 0.004 46.8 LNU183 24863.1 1.423 0.621 6.5 LNU201 28223.3 0.083 0.110 25.1 LNU201 28222.2 1.426 0.669 6.7 LNU201 28221.3 0.075 0.365 12.4 LNU268 26044.2 1.586 0.220 18.6 LNU268 26043.4 0.077 0.218 16.2 CONT. — 1.041 — 0.0 LNU268 26041.4 0.075 0.332 13.4 LNU11 28205.2 1.468 0.006 41.0 CONT. — 0.051 — 0.0 LNU11 28203.2 1.369 0.063 31.5 LNU107 14583.8 0.076 0.007 48.4 LNU11 28202.5 1.338 0.069 28.6 LNU107 14585.5 0.065 0.100 26.5 LNU11 28205.1 1.338 0.045 28.5 LNU107 14584.9 0.057 0.561 11.1 LNU11 28204.1 1.126 0.564 8.1 LNU116 14494.5 0.085 0.001 65.8 LNU11 28204.3 1.091 0.747 4.8 LNU116 14492.9 0.080 0.008 55.0 LNU112 28212.1 1.350 0.044 29.7 LNU116 14492.5 0.067 0.072 29.7 LNU112 28212.4 1.142 0.464 9.7 LNU116 14493.6 0.057 0.537 10.1 LNU14 27821.3 1.766 0.000 69.6 LNU121 27713.4 0.092 0.000 78.5 LNU14 27821.4 1.364 0.053 31.0 LNU121 27711.1 0.085 0.001 65.3 LNU14 27824.2 1.190 0.288 14.3 LNU121 25642.2 0.084 0.002 62.9 LNU14 27821.1 1.095 0.671 5.2 LNU121 27713.1 0.072 0.042 40.8 LNU183 24864.6 2.078 0.000 99.6 LNU126 25345.1 0.074 0.016 43.6 LNU183 24863.12 1.703 0.000 63.6 LNU126 25343.1 0.068 0.132 32.1 LNU183 24865.1 1.690 0.000 62.4 LNU126 25343.3 0.063 0.254 21.7 LNU183 24863.1 1.371 0.041 31.7 LNU126 25343.4 0.054 0.749 5.2 LNU191 28325.4 1.453 0.029 39.5 LNU158 27433.3 0.077 0.009 49.2 LNU191 28323.1 1.404 0.028 34.9 LNU158 27433.2 0.075 0.023 45.8 LNU191 28321.3 1.246 0.174 19.7 LNU158 27432.5 0.065 0.225 25.7 LNU191 28324.2 1.114 0.606 7.0 LNU158 27434.1 0.054 0.759 5.3 LNU201 28222.2 1.662 0.000 59.6 LNU177 24762.6 0.092 0.000 79.8 LNU201 28223.3 1.505 0.008 44.6 LNU177 24764.9 0.063 0.216 22.4 LNU201 28221.3 1.212 0.212 16.4 LNU177 24765.2 0.060 0.389 16.0 LNU201 28223.1 1.150 0.497 10.5 LNU182 25384.1 0.083 0.002 61.9 LNU268 26041.4 1.323 0.039 27.0 LNU182 27521.4 0.069 0.028 34.9 LNU268 26041.6 1.273 0.137 22.3 LNU182 25384.5 0.065 0.128 26.1 LNU268 26043.4 1.270 0.108 22.0 LNU182 25384.2 0.057 0.590 11.4 CONT. — 1.034 — 0.0 LNU2 27842.1 0.062 0.219 20.8 LNU107 14583.8 1.442 0.035 39.5 LNU2 27845.2 0.059 0.329 15.1 LNU107 14585.5 1.213 0.242 17.3 LNU2 27842.3 0.057 0.510 10.6 LNU107 14584.9 1.101 0.695 6.5 LNU225 25991.5 0.062 0.329 20.6 LNU116 14492.9 1.463 0.032 41.6 LNU225 25991.2 0.057 0.617 11.8 LNU116 14494.5 1.394 0.053 34.8 LNU239 26283.2 0.057 0.544 11.4 LNU116 14492.5 1.305 0.120 26.2 LNU57 27854.5 0.059 0.385 14.1 LNU121 27713.4 1.552 0.003 50.1 LNU57 27852.1 0.054 0.717 5.9 LNU121 25642.2 1.486 0.007 43.8 LNU83 27684.1 0.076 0.011 47.3 LNU121 27711.1 1.463 0.009 41.5 LNU83 27685.1 0.055 0.672 7.2 LNU121 27713.1 1.117 0.615 8.0 LNU83 27685.2 0.055 0.693 6.7 LNU126 25345.1 1.417 0.058 37.1 CONT. — 0.039 — 0.0 LNU126 25343.1 1.367 0.043 32.3 LNU107 14584.9 0.060 0.086 53.1 LNU126 25343.3 1.164 0.485 12.6 LNU107 14585.2 0.051 0.216 30.4 LNU158 27432.5 1.551 0.020 50.0 LNU107 14583.8 0.049 0.326 23.7 LNU158 27433.3 1.537 0.002 48.7 LNU116 14494.5 0.071 0.002 80.2 LNU158 27433.2 1.367 0.047 32.3 LNU116 14492.5 0.068 0.008 74.3 LNU177 24762.6 1.619 0.000 56.6 LNU116 14492.9 0.056 0.084 43.8 LNU177 24764.9 1.270 0.280 22.8 LNU116 14493.6 0.056 0.136 42.3 LNU177 24765.2 1.115 0.596 7.9 LNU116 14491.5 0.049 0.340 24.1 LNU182 25384.1 1.674 0.000 61.9 LNU121 27713.1 0.082 0.002 108.5 LNU182 27521.4 1.443 0.020 39.6 LNU121 27711.1 0.061 0.060 55.3 LNU182 25384.2 1.184 0.409 14.5 LNU121 27713.4 0.056 0.194 42.8 LNU2 27842.1 1.272 0.118 23.0 LNU121 25642.2 0.053 0.123 36.0 LNU2 27842.3 1.202 0.253 16.3 LNU126 25343.3 0.055 0.137 39.2 LNU225 25991.5 1.957 0.000 89.3 LNU126 25343.1 0.055 0.193 39.0 LNU225 25991.2 1.568 0.068 51.7 LNU126 25341.1 0.047 0.375 19.0 LNU239 26284.1 1.173 0.351 13.4 LNU158 27433.3 0.090 0.000 129.9 LNU57 27852.1 1.108 0.646 7.1 LNU158 27432.5 0.071 0.013 80.3 LNU83 27681.4 1.299 0.154 25.7 LNU158 27433.2 0.062 0.028 56.8 LNU83 27684.1 1.142 0.536 10.5 LNU177 24764.12 0.052 0.297 31.3 CONT. — 1.042 — 0.0 LNU177 24763.6 0.045 0.587 13.9 LNU107 14584.9 1.679 0.000 61.1 LNU177 24762.6 0.044 0.637 11.6 LNU107 14583.8 1.266 0.094 21.5 LNU182 25384.6 0.062 0.027 58.1 LNU107 14585.2 1.110 0.538 6.5 LNU182 25384.2 0.055 0.062 39.4 LNU116 14492.5 1.582 0.011 51.8 LNU2 27842.1 0.065 0.020 64.9 LNU116 14494.5 1.474 0.038 41.4 LNU2 27842.3 0.052 0.204 33.2 LNU116 14493.6 1.214 0.133 16.5 LNU2 27845.2 0.043 0.792 9.5 LNU121 25642.2 1.548 0.003 48.6 LNU225 25991.2 0.067 0.005 70.3 LNU121 27711.1 1.483 0.008 42.3 LNU225 25991.3 0.064 0.033 62.1 LNU121 27713.1 1.469 0.024 41.0 LNU225 25991.8 0.062 0.006 58.4 LNU121 27713.4 1.299 0.148 24.6 LNU225 25991.1 0.044 0.590 12.8 LNU126 25343.1 1.533 0.005 47.1 LNU239 26283.2 0.046 0.481 17.6 LNU126 25343.4 1.138 0.399 9.2 LNU239 26284.2 0.045 0.606 14.6 LNU126 25343.3 1.135 0.547 9.0 LNU239 26284.1 0.045 0.517 14.4 LNU158 27433.3 1.718 0.000 64.9 LNU239 26281.1 0.044 0.624 12.7 LNU158 27432.5 1.552 0.001 48.9 LNU57 27854.5 0.054 0.171 38.4 LNU158 27433.2 1.223 0.182 17.4 LNU57 27852.1 0.045 0.560 13.4 LNU177 24764.12 1.480 0.002 42.0 LNU83 27685.1 0.082 0.001 108.8 LNU177 24763.6 1.139 0.446 9.3 LNU83 27685.2 0.055 0.217 39.2 LNU177 24762.6 1.106 0.569 6.1 LNU83 27681.4 0.053 0.102 34.0 LNU182 25384.1 1.145 0.434 9.8 LNU182 25384.6 1.137 0.510 9.1 LNU182 25384.5 1.120 0.583 7.5 LNU2 27842.1 1.510 0.005 44.9 LNU2 27842.3 1.235 0.123 18.5 LNU2 25713.1 1.173 0.395 12.5 LNU225 25991.3 1.802 0.000 72.9 LNU225 25991.2 1.638 0.000 57.2 LNU225 25991.8 1.355 0.035 30.0 LNU225 25991.1 1.290 0.106 23.8 LNU239 26284.2 1.385 0.010 32.9 LNU57 27852.1 1.618 0.000 55.3 LNU57 27851.2 1.559 0.001 49.6 LNU57 27854.5 1.285 0.052 23.3 LNU57 27854.3 1.105 0.534 6.1 LNU83 27685.1 1.715 0.000 64.6 LNU83 27685.2 1.417 0.007 36.0 LNU83 27681.4 1.399 0.006 34.2 Table 66. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment. “RGR” = relative growth rate;

TABLE 67 Genes showing improved plant growth rate at nitrogen deficient conditions (T2 generation) RGR Of Roots Length Gene Name Event # Average p-value % increment CONTROL — 0.508 — 0.0 LNU100 14471.4 0.596 0.019 17.4 LNU100 14474.3 0.592 0.005 16.6 LNU100 14473.1 0.577 0.062 13.6 LNU100 14474.4 0.545 0.162 7.3 LNU104 25034.1 0.610 0.280 20.2 LNU104 25033.3 0.554 0.201 9.1 LNU213 24653.2 0.581 0.019 14.5 LNU213 24652.4 0.535 0.389 5.3 LNU213 24654.4 0.531 0.578 4.6 LNU213 24653.1 0.522 0.713 2.8 LNU218 24783.2 0.579 0.142 14.1 LNU4 25134.2 0.594 0.003 16.9 LNU4 25131.1 0.531 0.379 4.5 LNU48 24802.2 0.600 0.009 18.1 LNU48 24804.4 0.578 0.015 13.9 LNU8 25063.1 0.640 0.004 26.0 LNU94 24833.3 0.561 0.109 10.5 CONTROL — 0.573 — 0.0 LNU1 24684.1 0.638 0.209 11.2 LNU1 24681.3 0.625 0.192 9.1 LNU1 24682.2 0.617 0.679 7.6 LNU1 24681.1 0.597 0.605 4.1 LNU133 24744.3 0.624 0.454 8.9 LNU133 24741.1 0.589 0.728 2.7 LNU133 24742.2 0.587 0.795 2.4 LNU175 24732.4 0.666 0.280 16.2 LNU175 24732.1 0.613 0.486 6.9 LNU175 24731.2 0.596 0.623 4.0 LNU175 24734.4 0.592 0.710 3.3 LNU175 24733.4 0.586 0.713 2.3 LNU178 14611.5 0.692 0.028 20.7 LNU178 14611.4 0.624 0.288 8.9 LNU178 14614.5 0.616 0.404 7.4 LNU178 14611.1 0.610 0.435 6.4 LNU178 14612.1 0.587 0.696 2.5 LNU215 24661.4 0.639 0.125 11.5 LNU215 24664.3 0.634 0.227 10.6 LNU24 24973.1 0.626 0.223 9.2 LNU24 24971.4 0.608 0.532 6.1 LNU24 24971.3 0.602 0.471 5.0 LNU6 24992.3 0.639 0.244 11.4 LNU6 24994.2 0.594 0.617 3.6 LNU82 24824.3 0.596 0.551 4.0 LNU82 24824.1 0.596 0.664 4.0 LNU82 24823.1 0.596 0.623 3.9 LNU9 25001.1 0.648 0.159 13.1 LNU9 25003.1 0.647 0.066 12.9 LNU9 25001.2 0.624 0.297 8.9 LNU9 25001.3 0.592 0.636 3.3 CONTROL — 0.676 — 0.0 LNU120 25463.7 0.756 0.081 11.7 LNU120 25463.3 0.689 0.770 1.9 LNU132 14102.9 0.708 0.416 4.7 LNU132 14102.7 0.690 0.752 2.1 LNU140 14112.7 0.723 0.288 7.0 LNU140 14112.6 0.690 0.737 2.0 LNU180 24724.3 0.760 0.046 12.4 CONTROL — 0.559 — 0.0 LNU1 24681.1 0.707 0.009 26.5 LNU1 24682.1 0.698 0.025 24.8 LNU1 24683.2 0.628 0.204 12.4 LNU1 24684.1 0.578 0.720 3.3 LNU110 24953.2 0.682 0.044 22.0 LNU110 24952.3 0.593 0.566 6.0 LNU110 24954.3 0.589 0.576 5.4 LNU175 24734.4 0.670 0.058 19.9 LNU175 24732.2 0.645 0.220 15.4 LNU175 24732.1 0.607 0.424 8.5 LNU175 24733.1 0.602 0.491 7.7 LNU19 25151.1 0.607 0.536 8.6 LNU215 24663.4 0.729 0.007 30.4 LNU215 24661.4 0.699 0.013 24.9 LNU215 24664.2 0.683 0.040 22.2 LNU215 24663.3 0.668 0.126 19.5 LNU215 24663.1 0.632 0.187 13.1 LNU27 24873.1 0.662 0.093 18.4 LNU27 24873.4 0.631 0.234 12.9 LNU27 24871.4 0.575 0.763 2.9 LNU44 24924.2 0.724 0.009 29.4 LNU44 24922.3 0.717 0.013 28.3 LNU44 24923.3 0.668 0.073 19.5 LNU44 24924.3 0.610 0.456 9.1 LNU54 24901.2 0.786 0.002 40.5 LNU54 24902.4 0.733 0.003 31.2 LNU54 24903.3 0.653 0.227 16.8 LNU54 24902.7 0.645 0.151 15.3 LNU54 24903.5 0.634 0.241 13.4 LNU79 24882.2 0.682 0.026 22.0 LNU79 24881.1 0.679 0.057 21.4 LNU79 24884.4 0.675 0.041 20.7 LNU79 24884.3 0.626 0.303 12.1 LNU79 24883.2 0.604 0.426 8.0 CONTROL — 0.579 — 0.0 LNU109 24892.8 0.635 0.116 9.7 LNU109 24892.6 0.608 0.476 5.0 LNU109 24891.2 0.593 0.755 2.4 LNU110 24952.1 0.729 0.049 25.9 LNU110 24952.3 0.624 0.341 7.9 LNU133 24741.1 0.641 0.157 10.7 LNU133 24744.3 0.628 0.417 8.5 LNU19 25151.1 0.660 0.070 13.9 LNU27 24873.4 0.675 0.052 16.6 LNU44 24922.3 0.654 0.110 13.0 LNU54 24901.2 0.711 0.036 22.7 LNU6 24992.3 0.662 0.126 14.3 LNU6 24994.5 0.617 0.380 6.6 LNU79 24881.1 0.642 0.082 10.9 LNU79 24884.4 0.622 0.408 7.5 LNU79 24882.2 0.598 0.637 3.3 LNU79 24883.2 0.590 0.762 1.9 CONTROL — 0.530 — 0.0 LNU109 24892.8 0.658 0.032 24.3 LNU109 24891.2 0.573 0.550 8.1 LNU109 24891.5 0.552 0.715 4.2 LNU143 25972.1 0.665 0.035 25.5 LNU143 25975.3 0.619 0.137 16.8 LNU143 25971.2 0.593 0.274 12.0 LNU143 25971.5 0.588 0.323 11.0 LNU154 14604.6 0.619 0.131 16.9 LNU154 14602.8 0.591 0.440 11.6 LNU154 14604.7 0.588 0.371 11.0 LNU196 25532.2 0.675 0.013 27.4 LNU196 25534.1 0.645 0.113 21.9 LNU196 25533.1 0.596 0.226 12.6 LNU196 25532.1 0.554 0.782 4.5 LNU207 24642.4 0.656 0.046 23.8 LNU207 24644.18 0.593 0.272 12.0 LNU207 24642.5 0.557 0.654 5.2 LNU207 24644.13 0.546 0.800 3.1 LNU288 14562.7 0.624 0.142 17.8 LNU288 14564.9 0.602 0.177 13.6 LNU288 14562.1 0.586 0.349 10.6 LNU288 14562.9 0.568 0.454 7.2 LNU50 26024.2 0.615 0.205 16.1 LNU50 26023.2 0.603 0.254 13.9 LNU50 26023.5 0.586 0.290 10.6 LNU50 26025.4 0.580 0.453 9.6 LNU52 25723.2 0.681 0.034 28.6 LNU52 25721.4 0.604 0.276 14.1 LNU52 25721.3 0.566 0.561 6.9 CONTROL — 0.496 — 0.0 LNU143 25975.2 0.614 0.010 23.7 LNU143 25971.2 0.600 0.007 20.9 LNU143 25971.5 0.577 0.071 16.3 LNU143 25972.1 0.571 0.096 15.1 LNU143 25975.3 0.560 0.056 12.9 LNU154 14602.8 0.583 0.030 17.5 LNU154 14601.6 0.556 0.146 12.1 LNU207 24642.5 0.651 0.005 31.2 LNU207 24641.1 0.636 0.005 28.2 LNU207 24642.4 0.582 0.026 17.3 LNU211 24771.1 0.631 0.009 27.3 LNU211 24774.4 0.557 0.286 12.2 LNU211 24771.3 0.546 0.192 10.1 LNU52 25723.1 0.635 0.008 28.1 LNU52 25721.2 0.632 0.002 27.4 LNU52 25721.1 0.605 0.030 22.0 LNU52 25723.2 0.531 0.460 7.1 LNU69 14571.1 0.653 0.004 31.7 LNU69 14573.3 0.603 0.037 21.6 LNU69 14572.9 0.583 0.014 17.6 LNU69 14572.8 0.565 0.051 14.0 LNU69 14573.7 0.520 0.567 4.8 CONTROL — 0.489 — 0.0 LNU150 24841.9 0.673 0.034 37.7 LNU150 24842.9 0.631 0.096 29.1 LNU150 24843.5 0.533 0.611 9.1 LNU179 24631.6 0.674 0.032 38.1 LNU179 24631.9 0.673 0.037 37.8 LNU179 24632.5 0.608 0.166 24.5 LNU179 24631.7 0.598 0.193 22.5 LNU179 24632.7 0.535 0.585 9.4 LNU232 26001.5 0.572 0.345 17.1 LNU232 26003.7 0.568 0.349 16.3 LNU232 26003.3 0.561 0.394 14.9 LNU232 26001.2 0.552 0.454 13.1 LNU232 26003.6 0.523 0.689 7.0 LNU235 26185.3 0.674 0.037 37.9 LNU235 26184.4 0.628 0.114 28.6 LNU235 26185.2 0.611 0.146 25.2 LNU235 26184.2 0.606 0.175 24.0 LNU235 26182.1 0.556 0.429 13.9 LNU242 25474.1 0.646 0.076 32.2 LNU242 25473.1 0.635 0.095 30.1 LNU242 25473.3 0.596 0.205 22.0 LNU242 25471.1 0.542 0.524 11.0 LNU76 26423.1 0.676 0.030 38.5 LNU76 26425.1 0.645 0.069 32.0 LNU76 26421.2 0.605 0.193 23.9 LNU76 26421.1 0.568 0.383 16.2 LNU95 13985.11 0.663 0.046 35.7 LNU95 13985.15 0.632 0.092 29.3 LNU95 13985.19 0.628 0.115 28.5 LNU95 13985.12 0.565 0.375 15.7 LNU95 13985.16 0.565 0.369 15.6 CONTROL — 0.552 — 0.0 LNU118 14012.15 0.580 0.661 5.0 LNU150 24843.5 0.647 0.138 17.1 LNU150 24841.6 0.576 0.712 4.3 LNU150 24841.9 0.571 0.776 3.3 LNU179 24632.5 0.600 0.471 8.6 LNU179 24631.7 0.583 0.640 5.5 LNU179 24631.6 0.572 0.762 3.4 LNU232 26003.3 0.600 0.461 8.5 LNU232 26001.5 0.581 0.672 5.2 LNU235 26185.2 0.653 0.151 18.2 LNU235 26184.4 0.648 0.155 17.2 LNU235 26184.2 0.618 0.309 11.8 LNU242 25474.1 0.608 0.403 10.1 LNU288 14562.7 0.622 0.286 12.7 LNU288 14564.9 0.608 0.389 10.1 LNU288 14563.9 0.607 0.402 9.8 LNU288 14563.6 0.595 0.502 7.8 LNU288 14562.1 0.588 0.576 6.4 LNU76 26423.1 0.635 0.217 15.0 LNU76 26421.2 0.623 0.279 12.8 LNU76 26422.2 0.602 0.443 9.0 LNU95 13985.16 0.657 0.123 19.0 LNU95 13985.15 0.621 0.282 12.4 LNU95 13985.11 0.594 0.519 7.5 CONTROL — 0.580 — 0.0 LNU101 27632.7 0.664 0.135 14.5 LNU128 26511.5 0.645 0.229 11.2 LNU128 26515.3 0.594 0.788 2.5 LNU192 28315.2 0.675 0.088 16.5 LNU192 28313.2 0.671 0.114 15.7 LNU192 28312.2 0.645 0.212 11.3 LNU192 28313.3 0.606 0.632 4.6 LNU206 27622.1 0.648 0.211 11.8 LNU211 24771.1 0.745 0.004 28.5 LNU282 27562.1 0.686 0.067 18.3 LNU282 27563.3 0.667 0.138 15.1 LNU282 27563.1 0.653 0.174 12.6 LNU282 27565.2 0.616 0.513 6.2 LNU69 14571.1 0.706 0.020 21.7 LNU69 14573.5 0.610 0.578 5.2 LNU75 27572.2 0.616 0.530 6.2 LNU75 27572.1 0.613 0.539 5.8 CONTROL — 0.556 — 0.0 LNU101 27632.5 0.605 0.353 8.7 LNU101 27632.6 0.585 0.555 5.2 LNU118 14012.15 0.655 0.047 17.7 LNU118 14012.12 0.604 0.370 8.6 LNU128 26515.3 0.617 0.231 10.9 LNU128 26511.5 0.591 0.498 6.2 LNU206 27622.4 0.676 0.029 21.6 LNU206 27621.2 0.640 0.181 15.0 LNU206 27622.1 0.605 0.401 8.7 LNU249 26154.2 0.597 0.477 7.4 LNU249 26151.1 0.589 0.576 5.8 LNU249 26152.4 0.588 0.631 5.8 LNU249 26152.2 0.573 0.726 3.0 LNU282 27563.1 0.639 0.143 14.9 LNU282 27565.2 0.629 0.151 13.0 LNU282 27563.3 0.595 0.477 7.0 LNU282 27562.1 0.582 0.633 4.6 LNU288 14562.7 0.708 0.006 27.2 LNU288 14563.6 0.652 0.069 17.2 LNU288 14562.9 0.645 0.068 16.0 LNU288 14563.9 0.631 0.178 13.4 LNU288 14564.8 0.583 0.608 4.9 LNU75 27572.2 0.725 0.003 30.4 LNU75 27571.4 0.652 0.063 17.2 LNU75 27572.3 0.636 0.111 14.3 LNU75 27571.2 0.627 0.179 12.8 CONTROL — 0.596 — 0.0 LNU14 27821.3 0.619 0.681 3.9 LNU183 24863.1 0.615 0.740 3.2 LNU201 28222.2 0.639 0.479 7.3 LNU201 28223.1 0.615 0.747 3.1 LNU201 28222.3 0.613 0.765 2.9 LNU268 26041.6 0.661 0.241 10.8 LNU268 26044.2 0.647 0.386 8.6 LNU268 26045.1 0.619 0.666 3.9 CONTROL — 0.607 — 0.0 LNU11 28205.2 0.732 0.021 20.7 LNU11 28202.5 0.650 0.304 7.2 LNU11 28205.1 0.640 0.404 5.6 LNU112 28212.4 0.669 0.188 10.3 LNU112 28212.1 0.637 0.527 5.0 LNU14 27821.3 0.678 0.147 11.8 LNU14 27821.1 0.637 0.469 5.0 LNU14 27824.2 0.628 0.661 3.6 LNU14 27821.4 0.621 0.752 2.5 LNU183 24864.6 0.773 0.000 27.4 LNU183 24863.12 0.683 0.164 12.6 LNU183 24863.1 0.669 0.163 10.2 LNU191 28325.4 0.659 0.293 8.7 LNU191 28321.3 0.645 0.407 6.4 LNU191 28324.2 0.627 0.654 3.4 LNU191 28323.1 0.621 0.727 2.4 LNU201 28222.2 0.735 0.009 21.1 LNU201 28223.3 0.668 0.214 10.2 LNU201 28223.1 0.662 0.256 9.1 LNU201 28221.3 0.624 0.731 2.8 LNU268 26041.6 0.694 0.059 14.4 LNU268 26041.4 0.690 0.066 13.8 LNU268 26043.4 0.623 0.696 2.7 CONTROL — 0.580 — 0.0 LNU107 14584.9 0.616 0.595 6.3 LNU116 14492.5 0.654 0.142 12.8 LNU116 14492.9 0.644 0.255 11.0 LNU116 14494.5 0.610 0.603 5.2 LNU121 27711.1 0.715 0.026 23.3 LNU121 25642.2 0.629 0.325 8.5 LNU121 27713.4 0.613 0.581 5.7 LNU126 25345.1 0.612 0.569 5.4 LNU126 25343.1 0.598 0.765 3.1 LNU158 27433.3 0.652 0.199 12.3 LNU158 27433.2 0.647 0.220 11.5 LNU158 27432.5 0.644 0.297 11.0 LNU158 27434.1 0.614 0.523 5.9 LNU177 24764.9 0.642 0.365 10.7 LNU177 24762.6 0.628 0.398 8.2 LNU177 24764.12 0.620 0.512 6.9 LNU182 25384.1 0.699 0.065 20.5 LNU182 27521.4 0.611 0.610 5.3 LNU225 25991.5 0.657 0.230 13.2 LNU225 25991.8 0.648 0.196 11.8 LNU225 25991.2 0.615 0.602 6.0 LNU225 25991.3 0.603 0.668 4.0 LNU239 26284.2 0.597 0.754 3.0 LNU57 27854.5 0.618 0.456 6.6 LNU57 27852.1 0.615 0.577 6.0 LNU83 27682.1 0.677 0.105 16.8 LNU83 27681.4 0.631 0.462 8.7 CONTROL — 0.620 — 0.0 LNU107 14584.9 0.711 0.447 14.8 LNU107 14585.2 0.678 0.597 9.5 LNU107 14583.8 0.655 0.757 5.6 LNU116 14492.5 0.689 0.531 11.2 LNU121 27711.1 0.703 0.460 13.5 LNU121 27713.1 0.702 0.488 13.2 LNU121 25642.2 0.653 0.776 5.4 LNU126 25343.1 0.688 0.580 11.1 LNU126 25343.4 0.652 0.767 5.1 LNU158 27433.3 0.695 0.530 12.1 LNU158 27432.5 0.687 0.570 10.9 LNU158 27434.5 0.655 0.768 5.7 LNU177 24763.6 0.662 0.710 6.9 LNU177 24765.2 0.659 0.732 6.4 LNU177 24764.12 0.652 0.778 5.3 LNU182 25384.2 0.653 0.764 5.4 LNU2 27842.3 0.709 0.460 14.4 LNU2 27842.1 0.703 0.466 13.5 LNU225 25991.3 0.666 0.693 7.5 LNU225 25991.2 0.656 0.747 5.9 LNU225 25991.8 0.655 0.756 5.8 LNU225 25991.1 0.650 0.791 5.0 LNU57 27854.3 0.693 0.520 11.9 LNU57 27852.1 0.680 0.615 9.7 LNU57 27854.5 0.652 0.779 5.2 LNU83 27685.1 0.718 0.421 15.9 LNU83 27685.2 0.710 0.446 14.6 LNU83 27681.4 0.661 0.722 6.7 Table 67. “RGR” = relative growth rate;

TABLE 68 Genes showing improved plant growth rate at nitrogen deficient conditions (T1 generation) RGR Of RGR Of Leaf Area Roots Coverage Gene p- % Gene p- % Name Ave. value incr. Name Ave. value incr. CONT. 0.057 — 0.0 CONT. 0.440 — 0.0 LNU121 0.059 0.705 3.5 LNU121 0.620 0.003 41.0 LNU154 0.061 0.457 6.5 LNU150 0.464 0.668 5.4 CONT. 0.067 — 0.0 LNU154 0.456 0.793 3.7 LNU188 0.070 0.724 5.4 CONT. 0.585 — 0.0 LNU2 0.070 0.703 4.4 LNU127 0.717 0.182 22.6 LNU255 0.068 0.888 1.6 LNU188 0.639 0.589 9.2 LNU265 0.067 0.946 0.8 LNU217 0.616 0.741 5.3 LNU58 0.078 0.290 16.5 LNU239 0.652 0.570 11.4 LNU83 0.072 0.600 7.7 LNU265 0.766 0.076 30.9 CONT. 0.059 — 0.0 LNU275 1.396 0.000 138.7 LNU243 0.061 0.723 3.8 LNU32 0.643 0.615 9.9 LNU262 0.062 0.532 5.9 LNU57 0.714 0.134 22.1 LNU60 0.062 0.618 5.7 LNU58 1.365 0.000 133.3 LNU83 0.754 0.094 28.9 CONT. 0.423 — 0.0 LNU176 0.490 0.470 15.9 LNU214 0.524 0.228 23.9 LNU223 0.460 0.658 8.6 LNU233 0.529 0.217 25.1 LNU245 0.450 0.741 6.3 LNU247 0.671 0.019 58.6 LNU284 0.571 0.166 34.9 LNU289 0.574 0.115 35.6 LNU70 0.457 0.700 8.1 LNU85 0.500 0.436 18.1 CONT. 0.541 — 0.0 LNU225 0.661 0.108 22.2 LNU262 0.587 0.477 8.5 LNU266 0.606 0.382 12.1 LNU29 0.553 0.840 2.3 LNU51 0.557 0.826 3.0 LNU60 0.779 0.008 44.1 CONT. 0.454 — 0.0 LNU171 0.767 0.04 70.0 LNU222-H6 0.4711 0.88 4.0 Table 68 . “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment. “RGR” = relative growth rate;

TABLE 69 Genes showing improved plant growth rate at nitrogen deficient conditions (T1 generation) RGR Of Roots Length Gene Name Event # Average p-value % increment CONTROL — 0.477 — 0.0 LNU121 27711 0.512 0.373 7.2 LNU154 14601 0.501 0.551 5.0 LNU68 14031 0.498 0.586 4.3 CONTROL — 0.542 — 0.0 LNU127 27601 0.545 0.939 0.6 LNU217 28231 0.576 0.469 6.3 LNU265 30261 0.548 0.886 1.2 LNU275 30341 0.645 0.030 19.0 LNU57 27851 0.595 0.226 9.8 LNU58 27671 0.803 0.000 48.1 LNU83 27681 0.626 0.073 15.5 CONTROL — 0.462 — 0.0 LNU176 29501 0.472 0.815 2.2 LNU214 29521 0.463 0.960 0.3 LNU223 29561 0.483 0.503 4.6 LNU233 29461 0.486 0.538 5.2 LNU245 29831 0.462 0.996 0.0 LNU247 29571 0.521 0.147 12.9 LNU289 29741 0.485 0.579 5.1 LNU70 29591 0.487 0.460 5.6 LNU85 29551 0.504 0.380 9.2 CONTROL — 0.551 — 0.0 LNU60 29991 0.590 0.365 7.1 Table 69. “RGR” = relative growth rate;

The genes listed in Tables 70, 71, 72 and 73 improved plant NUE when grown at standard nitrogen concentration levels. These genes produced larger plant biomass (plant fresh and dry weight and leaf area) when grown under standard nitrogen growth conditions, compared to control plants. Larger plant biomass under this growth conditions indicates the high ability of the plant to better metabolize the nitrogen present in the medium. The genes were cloned under the regulation of a constitutive promoter (At6669) or root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one tissue culture assay and the results obtained where positive as well. Event with p-value <0.1 was considered statistically significant

TABLE 70 Genes showing improved plant performance at standard nitrogen growth conditions (T2 generation) Plant Biomass Plant Biomass Dry Fresh weight [gr.] Weight [gr] Gene Name Event # Ave. p-value % incr. Gene Name Event # Ave. Ave. p-value CONT. — 0.130 — 0.0 CONT. — 0.005 — 0.0 LNU100 14474.3 0.199 0.219 52.9 LNU100 14474.3 0.010 0.123 102.5 LNU100 14474.4 0.137 0.727 5.3 LNU100 14474.4 0.006 0.378 23.5 LNU104 25034.1 0.184 0.296 41.6 LNU104 25033.3 0.007 0.224 39.5 LNU104 25033.3 0.170 0.199 30.9 LNU213 24654.4 0.011 0.107 108.3 LNU213 24654.4 0.228 0.080 75.1 LNU213 24653.2 0.011 0.003 104.9 LNU213 24653.2 0.212 0.012 62.6 LNU213 24651.1 0.007 0.073 36.1 LNU213 24651.1 0.160 0.114 22.6 LNU218 24783.2 0.012 0.100 124.8 LNU218 24783.2 0.239 0.098 84.1 LNU218 24781.7 0.007 0.089 28.4 LNU218 24781.7 0.156 0.144 19.7 LNU4 25134.1 0.007 0.070 38.6 LNU4 25134.1 0.165 0.065 26.5 LNU48 24803.2 0.008 0.139 47.3 LNU48 24803.2 0.177 0.060 35.7 LNU48 24802.2 0.007 0.102 32.3 LNU48 24802.2 0.155 0.420 19.2 LNU48 24804.4 0.006 0.382 18.2 LNU48 24804.4 0.138 0.716 5.7 LNU8 25063.1 0.008 0.045 63.3 LNU8 25063.1 0.192 0.136 47.6 LNU8 25062.2 0.007 0.183 44.9 LNU8 25062.2 0.173 0.236 32.8 LNU8 25063.6 0.006 0.207 19.2 LNU8 25063.6 0.140 0.548 7.6 LNU94 24833.3 0.006 0.234 19.7 CONT. — 0.115 — 0.0 LNU94 24834.1 0.006 0.607 11.4 LNU1 24681.3 0.162 0.123 40.8 CONT. — 0.006 — 0.0 LNU1 24682.2 0.125 0.542 9.1 LNU1 24681.3 0.009 0.141 44.4 LNU1 24684.1 0.122 0.376 6.3 LNU1 24682.2 0.007 0.548 12.0 LNU1 24682.1 0.121 0.387 5.3 LNU133 24741.1 0.015 0.046 142.4 LNU133 24741.1 0.264 0.035 130.1 LNU133 24744.3 0.014 0.033 120.8 LNU133 24744.3 0.238 0.054 107.4 LNU175 24732.1 0.011 0.086 68.4 LNU175 24734.4 0.179 0.058 55.6 LNU175 24734.4 0.010 0.067 52.4 LNU175 24732.1 0.173 0.101 50.8 LNU175 24732.4 0.008 0.264 33.2 LNU175 24732.4 0.155 0.181 35.2 LNU175 24731.2 0.007 0.367 16.0 LNU175 24731.2 0.145 0.100 26.7 LNU178 14614.5 0.009 0.121 39.2 LNU178 14614.5 0.153 0.109 32.8 LNU178 14611.5 0.009 0.060 37.2 LNU178 14611.5 0.148 0.091 28.6 LNU178 14611.1 0.007 0.505 10.0 LNU178 14611.1 0.134 0.313 16.7 LNU215 24664.3 0.013 0.002 104.8 LNU215 24664.3 0.231 0.004 100. 8 LNU215 24661.4 0.007 0.498 13.6 LNU215 24661.4 0.136 0.260 18.1 LNU24 24973.1 0.010 0.156 67.2 LNU24 24971.4 0.178 0.025 55.3 LNU24 24971.4 0.009 0.034 40.8 LNU24 24973.1 0.172 0.126 50.1 LNU24 24971.2 0.007 0.253 19.2 LNU24 24971.2 0.135 0.129 17.7 LNU6 24992.3 0.016 0.075 150.4 LNU6 24992.3 0.308 0.086 168.0 LNU82 24823.1 0.010 0.231 63.2 LNU6 24993.3 0.135 0.561 17.3 LNU9 25001.3 0.011 0.004 81.6 LNU6 24994.1 0.123 0.466 7.1 LNU9 25001.1 0.007 0.657 5.6 LNU6 24994.5 0.118 0.679 3.0 CONT. — 0.004 — 0.0 LNU82 24823.1 0.198 0.212 72.8 LNU120 25463.7 0.007 0.030 71.6 LNU9 25001.3 0.201 0.011 75.4 LNU120 25463.3 0.005 0.152 29.7 LNU9 25001.1 0.128 0.321 11.2 LNU120 25463.6 0.005 0.070 22.6 CONT. — 0.090 — 0.0 LNU124 14501.7 0.006 0.008 65.2 LNU120 25463.7 0.144 0.021 60.4 LNU124 14501.1 0.005 0.070 35.5 LNU120 25463.3 0.126 0.003 40.2 LNU124 14502.7 0.004 0.578 5.8 LNU120 25463.6 0.120 0.279 33.0 LNU132 14102.7 0.005 0.136 34.2 LNU120 25464.1 0.095 0.707 5.6 LNU132 14101.9 0.004 0.507 12.9 LNU124 14501.7 0.151 0.006 68.2 LNU132 14102.9 0.004 0.330 9.0 LNU124 14501.1 0.132 0.065 47.0 LNU132 14102.6 0.004 0.650 5.2 LNU124 14502.1 0.117 0.342 30.1 LNU140 14112.7 0.007 0.192 72.3 LNU124 14502.7 0.097 0.521 7.9 LNU140 14111.6 0.005 0.301 20.0 LNU132 14102.7 0.134 0.043 48.6 LNU180 24724.3 0.009 0.010 124.5 LNU132 14102.9 0.109 0.119 20.7 LNU180 24723.3 0.006 0.280 47.7 LNU132 14101.9 0.106 0.158 18.3 LNU196 25534.1 0.006 0.024 63.9 LNU140 14112.7 0.142 0.291 58.4 LNU196 25533.3 0.005 0.509 18.7 LNU140 14111.6 0.117 0.190 29.7 LNU196 25533.1 0.005 0.110 16.8 LNU140 14114.8 0.097 0.690 8.4 LNU20 24933.2 0.005 0.323 34.8 LNU180 24724.3 0.172 0.000 91.7 LNU36 25562.3 0.006 0.034 47.7 LNU180 24723.3 0.148 0.172 64.5 LNU36 25562.4 0.005 0.040 31.0 LNU180 24721.4 0.100 0.586 11.3 LNU36 25561.2 0.004 0.628 3.9 LNU180 24724.1 0.096 0.736 7.2 LNU71 25853.4 0.007 0.004 92.9 LNU196 25534.1 0.141 0.012 56.4 LNU71 25852.4 0.005 0.206 23.9 LNU196 25533.3 0.114 0.448 27.2 CONT. — 0.004 — 0.0 LNU196 25533.1 0.102 0.223 13.9 LNU1 24681.3 0.008 0.000 108.6 LNU20 24933.2 0.132 0.237 46.5 LNU1 24683.2 0.004 0.244 15.5 LNU20 24933.1 0.094 0.794 4.7 LNU110 24953.3 0.005 0.197 39.9 LNU36 25562.3 0.134 0.001 48.8 LNU110 24952.3 0.005 0.321 35.9 LNU36 25562.4 0.130 0.212 44.1 LNU175 24732.2 0.009 0.151 132.3 LNU36 25561.2 0.095 0.689 5.1 LNU175 24733.4 0.007 0.054 98.4 LNU71 25853.4 0.165 0.001 83.4 LNU175 24732.1 0.004 0.537 13.5 LNU71 25852.4 0.147 0.020 63.7 LNU175 24734.4 0.004 0.573 8.0 CONT. — 0.125 — 0.0 LNU19 25151.1 0.008 0.031 107.2 LNU1 24681.3 0.180 0.092 44.5 LNU19 25153.3 0.006 0.059 52.9 LNU110 24952.3 0.148 0.419 18.6 LNU19 25153.1 0.004 0.328 10.1 LNU175 24732.2 0.199 0.237 59.6 LNU215 24663.4 0.013 0.209 259.4 LNU175 24733.4 0.177 0.071 41.9 LNU215 24663.1 0.007 0.365 95.0 LNU19 25151.1 0.185 0.230 48.6 LNU215 24663.3 0.005 0.123 30.4 LNU215 24663.4 0.203 0.008 63.3 LNU215 24664.2 0.004 0.411 17.5 LNU215 24663.3 0.134 0.681 7.9 LNU27 24873.1 0.009 0.000 131.0 LNU27 24873.1 0.210 0.005 68.6 LNU27 24873.4 0.005 0.420 29.1 LNU27 24873.4 0.152 0.570 21.9 LNU44 24924.2 0.021 0.318 464.5 LNU44 24924.3 0.207 0.068 66.3 LNU44 24924.3 0.009 0.095 140.5 LNU44 24923.1 0.150 0.444 20.2 LNU44 24923.1 0.006 0.185 69.2 LNU44 24924.2 0.138 0.646 10.6 LNU44 24922.3 0.005 0.387 26.4 LNU54 24903.5 0.191 0.146 53.5 LNU54 24903.5 0.008 0.035 107.9 LNU54 24903.3 0.145 0.354 16.1 LNU54 24903.3 0.006 0.010 58.3 LNU54 24901.2 0.138 0.645 11.0 LNU79 24881.1 0.008 0.016 119.4 LNU79 24884.4 0.212 0.005 70.5 LNU79 24884.4 0.008 0.062 112.6 LNU79 24881.1 0.177 0.036 41.9 LNU79 24884.3 0.005 0.166 47.4 LNU79 24884.3 0.167 0.173 33.8 LNU79 24882.2 0.004 0.169 18.2 CONT. — 0.132 — 0.0 CONT — 0.006 — 0.0 LNU109 24891.2 0.198 0.021 49.7 LNU109 24891.2 0.010 0.003 69.3 LNU109 24892.6 0.180 0.074 36.2 LNU109 24892.6 0.009 0.113 41.8 LNU109 24891.5 0.165 0.048 25.0 LNU109 24891.5 0.009 0.109 39.3 LNU109 24892.5 0.160 0.367 20.9 LNU109 24892.5 0.008 0.290 26.2 LNU110 24952.1 0.241 0.008 81.9 LNU110 24952.1 0.012 0.000 100.4 LNU110 24953.2 0.208 0.030 57.3 LNU110 24954.1 0.010 0.019 66.4 LNU110 24954.1 0.194 0.011 46.8 LNU110 24953.2 0.010 0.013 63.1 LNU110 24952.3 0.183 0.046 38.1 LNU110 24952.3 0.009 0.061 54.5 LNU110 24954.3 0.142 0.445 7.7 LNU110 24954.3 0.008 0.030 25.8 LNU133 24741.2 0.249 0.014 88.2 LNU133 24741.2 0.014 0.019 127.0 LNU133 24744.3 0.232 0.011 75.6 LNU133 24741.1 0.011 0.004 82.4 LNU133 24741.1 0.229 0.010 73.5 LNU133 24744.3 0.011 0.033 76.2 LNU133 24742.2 0.199 0.123 50.5 LNU133 24744.2 0.010 0.015 68.0 LNU133 24744.2 0.186 0.055 40.8 LNU133 24742.2 0.010 0.019 63.1 LNU19 25151.1 0.253 0.026 91.0 LNU19 25151.1 0.012 0.020 104.5 LNU19 25153.3 0.166 0.349 25.3 LNU19 25153.3 0.009 0.158 43.4 LNU27 24873.4 0.293 0.029 121.4 LNU19 25151.11 0.006 0.617 3.3 LNU27 24871.4 0.159 0.476 20.6 LNU27 24873.4 0.015 0.032 150.8 LNU44 24922.3 0.218 0.021 64.5 LNU27 24871.4 0.007 0.420 20.1 LNU44 24923.1 0.153 0.200 15.6 LNU27 24873.1 0.006 0.737 3.7 LNU44 24924.3 0.151 0.470 14.4 LNU44 24922.3 0.011 0.009 84.0 LNU44 24923.3 0.139 0.676 5.3 LNU44 24923.1 0.008 0.058 27.9 LNU54 24903.5 0.286 0.027 116.3 LNU44 24924.3 0.008 0.214 27.0 LNU54 24902.4 0.221 0.294 67.4 LNU54 24903.5 0.015 0.022 142.6 LNU54 24901.2 0.159 0.479 19.9 LNU54 24902.4 0.011 0.184 83.6 LNU6 24992.3 0.240 0.066 81.6 LNU54 24901.2 0.009 0.194 43.9 LNU6 24994.5 0.240 0.121 81.6 LNU6 24992.3 0.012 0.082 91.4 LNU6 24994.1 0.166 0.219 25.6 LNU6 24994.5 0.012 0.172 90.2 LNU79 24881.1 0.255 0.038 92.8 LNU6 24994.1 0.009 0.167 40.2 LNU79 24882.2 0.232 0.026 75.6 LNU6 24994.2 0.008 0.345 24.6 LNU79 24884.4 0.226 0.163 70.7 LNU79 24881.1 0.012 0.007 99.6 LNU79 24883.2 0.198 0.041 49.9 LNU79 24882.2 0.012 0.031 94.7 LNU79 24884.3 0.190 0.074 43.8 LNU79 24883.2 0.011 0.011 88.1 CONT. — 0.119 — 0.0 LNU79 24884.4 0.010 0.083 62.7 LNU109 24892.8 0.195 0.058 63.2 LNU79 24884.3 0.010 0.028 61.1 LNU109 24891.5 0.188 0.135 57.1 CONT. — 0.005 — 0.0 LNU109 24891.2 0.139 0.570 16.6 LNU109 24892.8 0.010 0.063 89.5 LNU154 14604.7 0.162 0.247 35.9 LNU109 24891.5 0.008 0.243 50.7 LNU154 14604.6 0.131 0.719 9.4 LNU109 24891.2 0.007 0.486 26.5 LNU196 25532.2 0.223 0.133 86.8 LNU143 25975.2 0.007 0.556 21.0 LNU196 25534.1 0.129 0.790 7.6 LNU154 14604.7 0.009 0.192 56.2 LNU207 24642.5 0.226 0.071 89.3 LNU196 25532.2 0.011 0.119 108.7 LNU52 25723.2 0.168 0.216 40.9 LNU196 25534.1 0.006 0.650 16.9 LNU52 25721.4 0.128 0.799 7.2 LNU207 24642.5 0.010 0.121 82.6 CONT. — 0.128 — 0.0 LNU50 26025.4 0.006 0.785 11.4 LNU154 14601.6 0.171 0.487 33.7 LNU52 25723.2 0.008 0.335 38.8 LNU207 24642.5 0.220 0.093 72.5 LNU52 25721.3 0.006 0.723 16.9 LNU207 24642.4 0.181 0.203 41.6 CONT. — 0.006 — 0.0 LNU211 24771.1 0.200 0.078 56.5 LNU154 14601.6 0.009 0.459 48.4 LNU52 25721.4 0.221 0.057 73.3 LNU207 24642.5 0.011 0.016 69.6 LNU52 25721.1 0.172 0.133 34.9 LNU207 24642.4 0.009 0.061 41.8 LNU52 25723.1 0.154 0.093 20.9 LNU211 24771.1 0.011 0.128 64.9 LNU69 14571.1 0.224 0.035 75.6 LNU52 25721.4 0.011 0.050 75.5 LNU69 14572.8 0.141 0.441 10.5 LNU52 25721.1 0.008 0.231 33.1 CONT. — 0.120 — 0.0 LNU52 25723.1 0.007 0.628 5.6 LNU150 24843.9 0.179 0.091 49.0 LNU69 14571.1 0.010 0.057 49.2 LNU150 24841.9 0.178 0.015 47.8 CONT. — 0.005 — 0.0 LNU150 24843.5 0.167 0.002 38.6 LNU150 24841.9 0.009 0.021 64.5 LNU150 24842.9 0.143 0.103 18.6 LNU150 24843.5 0.008 0.003 52.8 LNU179 24632.5 0.127 0.762 5.6 LNU150 24843.9 0.007 0.017 38.0 LNU179 24631.7 0.126 0.771 4.9 LNU150 24842.9 0.007 0.112 30.5 LNU232 26003.7 0.130 0.584 8.4 LNU232 26003.7 0.007 0.248 23.6 LNU232 26001.5 0.130 0.608 7.8 LNU232 26001.5 0.006 0.712 4.5 LNU242 25474.1 0.167 0.058 38.9 LNU235 26184.4 0.006 0.747 4.5 LNU242 25473.1 0.142 0.301 17.8 LNU242 25474.1 0.008 0.167 43.1 LNU76 26421.2 0.164 0.265 36.3 LNU242 25473.1 0.007 0.191 27.3 LNU76 26421.1 0.158 0.389 31.9 LNU76 26421.1 0.008 0.060 51.5 LNU76 26422.2 0.133 0.607 11.0 LNU76 26421.2 0.008 0.154 40.3 LNU95 13985.1 0.186 0.040 55.1 LNU76 26422.2 0.007 0.226 26.4 LNU95 13985.15 0.139 0.296 15.8 LNU76 26425.1 0.006 0.700 4.5 LNU95 13985.16 0.136 0.281 12.9 LNU95 13985.11 0.009 0.069 76.1 LNU95 13985.12 0.129 0.576 7.3 LNU95 13985.15 0.008 0.146 39.8 LNU95 13985.19 0.128 0.702 6.8 LNU95 13985.19 0.006 0.641 12.9 CONT. — 0.129 — 0.0 LNU95 13985.16 0.006 0.466 10.1 LNU118 14013.8 0.227 0.027 75.7 CONT. — 0.006 — 0.0 LNU118 14013.6 0.219 0.057 69.9 LNU118 14013.8 0.011 0.008 80.1 LNU118 14012.12 0.187 0.147 45.1 LNU118 14013.6 0.010 0.015 67.7 LNU118 14012.15 0.179 0.077 38.8 LNU118 14012.12 0.010 0.060 55.3 LNU118 14012.14 0.134 0.788 3.7 LNU118 14012.15 0.009 0.147 38.8 LNU150 24842.9 0.248 0.035 91.7 LNU118 14012.14 0.008 0.152 20.9 LNU150 24841.9 0.161 0.111 24.7 LNU150 24842.9 0.012 0.066 89.8 LNU150 24841.6 0.150 0.150 16.3 LNU150 24841.9 0.008 0.019 30.8 LNU150 24843.5 0.144 0.664 11.6 LNU150 24843.5 0.008 0.389 20.4 LNU179 24632.7 0.186 0.022 44.1 LNU150 24841.6 0.007 0.632 5.9 LNU179 24631.7 0.173 0.184 33.8 LNU179 24632.7 0.011 0.015 73.3 LNU179 24631.9 0.137 0.716 6.3 LNU179 24631.7 0.008 0.235 27.6 LNU232 26001.5 0.187 0.033 44.6 LNU232 26001.5 0.009 0.014 41.2 LNU232 26003.3 0.147 0.238 13.5 LNU232 26003.6 0.007 0.469 9.1 LNU232 26003.6 0.136 0.661 5.6 LNU232 26003.3 0.007 0.439 7.5 LNU235 26184.4 0.278 0.001 115.4 LNU235 26184.4 0.014 0.006 124.7 LNU235 26184.2 0.243 0.004 88.4 LNU235 26185.2 0.011 0.000 77.7 LNU235 26185.2 0.226 0.017 75.1 LNU235 26184.2 0.011 0.000 72.5 LNU235 26182.1 0.137 0.751 6.0 LNU235 26182.1 0.007 0.064 19.6 LNU242 25474.1 0.158 0.238 22.6 LNU242 25474.1 0.007 0.176 13.5 LNU288 14563.9 0.274 0.006 112.2 LNU288 14563.9 0.016 0.002 152.4 LNU288 14562.1 0.196 0.026 51.7 LNU288 14562.1 0.010 0.001 62.9 LNU288 14564.9 0.172 0.261 33.5 LNU288 14564.9 0.008 0.366 28.4 LNU288 14563.6 0.144 0.420 11.2 LNU288 14562.7 0.007 0.580 20.0 LNU288 14562.7 0.143 0.684 10.5 LNU288 14563.6 0.007 0.207 15.9 LNU76 26421.2 0.175 0.261 35.2 LNU76 26421.2 0.008 0.238 30.8 LNU76 26422.2 0.153 0.210 18.4 LNU76 26422.2 0.008 0.325 22.0 LNU76 26423.1 0.142 0.444 9.8 LNU76 26423.1 0.006 0.747 3.9 LNU95 13985.16 0.265 0.008 105.4 LNU95 13985.16 0.014 0.015 117.5 LNU95 13985.12 0.198 0.016 53.2 LNU95 13985.12 0.010 0.052 67.7 LNU95 13985.15 0.183 0.016 41.3 LNU95 13985.15 0.010 0.024 52.5 CONT. — 0.144 — 0.0 LNU95 13985.19 0.007 0.340 12.7 LNU101 27632.1 0.177 0.162 23.0 CONT. — 0.007 — 0.0 LNU101 27635.1 0.159 0.359 10.4 LNU101 27635.1 0.008 0.360 9.9 LNU128 26515.3 0.181 0.160 26.1 LNU101 27632.1 0.007 0.800 4.2 LNU128 26515.2 0.161 0.642 12.0 LNU128 26515.3 0.010 0.119 39.9 LNU192 28312.2 0.164 0.707 13.7 LNU128 26515.2 0.009 0.223 34.5 LNU192 28315.2 0.163 0.168 13.6 LNU192 28315.2 0.009 0.052 26.0 LNU192 28313.2 0.151 0.614 5.1 LNU192 28313.2 0.008 0.224 17.8 LNU206 27621.1 0.160 0.460 11.0 LNU206 27621.1 0.007 0.783 6.0 LNU211 24771.1 0.250 0.046 73.5 LNU211 24771.1 0.013 0.024 85.5 LNU211 24773.1 0.182 0.452 26.2 LNU211 24773.1 0.009 0.342 29.5 LNU282 27563.3 0.180 0.036 24.8 LNU282 27563.3 0.009 0.164 32.7 LNU69 14571.1 0.199 0.150 38.2 LNU69 14571.1 0.011 0.056 57.4 LNU69 14573.5 0.148 0.713 2.7 LNU69 14573.5 0.009 0.003 23.5 LNU75 27572.1 0.185 0.012 28.7 LNU69 14572.9 0.007 0.741 2.4 LNU75 27572.2 0.162 0.409 12.3 LNU75 27572.1 0.009 0.020 29.9 CONT. — 0.122 — 0.0 LNU75 27572.2 0.009 0.095 28.5 LNU101 27632.5 0.184 0.165 50.5 CONT. — 0.005 — 0.0 LNU118 14013.6 0.199 0.023 62.9 LNU101 27632.5 0.009 0.151 69.4 LNU118 14012.15 0.167 0.037 36.3 LNU118 14013.6 0.010 0.026 87.5 LNU118 14013.9 0.147 0.325 20.0 LNU118 14012.15 0.009 0.029 68.0 LNU206 27621.2 0.203 0.058 66.4 LNU118 14013.9 0.007 0.194 28.5 LNU249 26153.1 0.221 0.052 81.0 LNU118 14013.8 0.006 0.581 15.5 LNU249 26152.4 0.137 0.578 12.4 LNU118 14012.12 0.006 0.582 7.7 LNU282 27563.1 0.199 0.029 63.0 LNU206 27621.2 0.008 0.034 56.8 LNU288 14563.9 0.247 0.017 101.9 LNU206 27621.1 0.006 0.604 9.0 LNU288 14564.8 0.225 0.000 84.2 LNU249 26153.1 0.010 0.027 86.1 LNU288 14562.7 0.175 0.197 43.4 LNU249 26152.4 0.006 0.799 5.3 LNU288 14562.9 0.167 0.185 36.6 LNU282 27563.1 0.009 0.021 68.9 LNU288 14563.6 0.149 0.366 21.9 LNU288 14563.9 0.013 0.001 135.7 LNU75 27571.4 0.216 0.002 76.8 LNU288 14564.8 0.011 0.001 99.1 LNU75 27572.3 0.199 0.029 62.9 LNU288 14562.7 0.009 0.270 68.0 LNU75 27571.2 0.166 0.041 35.9 LNU288 14562.9 0.009 0.100 62.9 LNU75 27572.2 0.165 0.174 35.3 LNU288 14563.6 0.006 0.439 17.9 CONT. — 0.130 — 0.0 LNU75 27571.4 0.010 0.007 83.8 LNU11 28204.1 0.145 0.596 11.2 LNU75 27572.3 0.008 0.109 57.3 LNU11 28204.3 0.144 0.455 11.0 LNU75 27572.2 0.008 0.162 48.5 LNU183 24863.12 0.180 0.020 38.4 LNU75 27571.2 0.008 0.037 44.8 LNU183 24863.1 0.149 0.202 14.3 CONT. — 0.006 — 0.0 LNU183 24865.1 0.135 0.742 4.1 LNU11 28204.3 0.007 0.585 6.6 LNU268 26044.2 0.180 0.339 38.8 LNU11 28204.3 0.007 0.685 5.8 CONT. — 0.110 — 0.0 LNU183 24863.12 0.008 0.306 25.6 LNU11 28205.1 0.150 0.052 35.7 LNU268 26044.2 0.008 0.393 32.8 LNU11 28205.2 0.150 0.041 35.6 CONT. — 0.005 — 0.0 LNU11 28204.1 0.127 0.270 14.9 LNU11 28205.1 0.007 0.134 30.1 LNU11 28203.2 0.114 0.769 3.7 LNU11 28205.2 0.007 0.117 24.5 LNU11 28204.3 0.114 0.794 3.1 LNU11 28204.3 0.006 0.214 16.2 LNU112 28212.3 0.132 0.202 19.4 LNU11 28203.2 0.006 0.430 10.6 LNU112 28212.4 0.126 0.280 14.2 LNU112 28212.4 0.006 0.448 10.2 LNU14 27821.3 0.164 0.101 49.0 LNU14 27821.3 0.008 0.119 49.1 LNU14 27821.4 0.116 0.729 4.8 LNU183 24865.1 0.012 0.000 118.5 LNU183 24863.1 0.263 0.045 138.7 LNU183 24863.1 0.010 0.002 88.0 LNU183 24865.1 0.254 0.000 130.0 LNU183 24863.12 0.010 0.028 82.4 LNU183 24864.6 0.208 0.017 88.8 LNU183 24864.6 0.009 0.001 69.0 LNU183 24863.12 0.199 0.004 80.5 LNU191 28323.1 0.008 0.147 40.3 LNU191 28324.2 0.154 0.034 39.9 LNU191 28324.2 0.008 0.058 39.4 LNU191 28325.4 0.152 0.015 38.2 LNU191 28325.4 0.007 0.023 34.7 LNU191 28323.1 0.145 0.229 31.4 LNU191 28325.3 0.006 0.413 18.5 LNU191 28325.3 0.136 0.156 23.3 LNU201 28222.2 0.010 0.022 85.6 LNU201 28222.2 0.216 0.005 96.0 LNU201 28221.3 0.007 0.124 25.5 LNU201 28223.3 0.149 0.123 35.0 LNU201 28223.3 0.006 0.741 6.0 LNU201 28221.3 0.135 0.148 22.5 LNU268 26041.4 0.008 0.016 54.2 LNU201 28222.3 0.118 0.612 7.3 LNU268 26043.4 0.007 0.077 30.1 LNU268 26043.4 0.173 0.019 56.8 LNU268 26045.1 0.007 0.334 21.0 LNU268 26041.4 0.168 0.039 52.0 CONT. — 0.004 — 0.0 LNU268 26045.1 0.144 0.074 30.2 LNU107 14584.9 0.007 0.003 75.5 LNU268 26041.6 0.126 0.498 14.6 LNU107 14585.5 0.006 0.369 45.7 LNU268 26044.2 0.119 0.679 7.6 LNU107 14583.8 0.005 0.059 44.4 CONT. — 0.079 — 0.0 LNU107 14583.7 0.004 0.660 6.0 LNU107 14584.9 0.159 0.047 100.2 LNU116 14493.6 0.006 0.045 67.5 LNU107 14585.5 0.143 0.183 79.7 LNU116 14494.5 0.006 0.005 51.7 LNU107 14583.8 0.120 0.064 50.6 LNU116 14492.9 0.006 0.015 49.0 LNU107 14583.7 0.094 0.281 18.2 LNU116 14492.5 0.004 0.421 9.9 LNU116 14493.6 0.201 0.106 152.6 LNU12 27371.1 0.004 0.750 4.0 LNU116 14494.5 0.125 0.020 56.9 LNU12 27372.5 0.004 0.737 4.0 LNU116 14492.9 0.124 0.067 55.8 LNU121 25642.2 0.009 0.002 150.3 LNU116 14492.5 0.110 0.012 38.2 LNU121 27713.1 0.007 0.000 88.1 LNU121 25642.2 0.193 0.010 142.4 LNU121 27713.4 0.007 0.017 85.4 LNU121 27713.1 0.168 0.002 111.8 LNU121 27711.1 0.007 0.037 73.5 LNU121 27711.1 0.153 0.000 92.5 LNU126 25345.1 0.008 0.008 99.3 LNU121 27713.4 0.148 0.002 86.8 LNU126 25343.1 0.007 0.071 80.8 LNU126 25345.1 0.163 0.006 104.8 LNU126 25343.3 0.007 0.000 76.2 LNU126 25343.3 0.154 0.020 93.9 LNU126 25343.4 0.004 0.144 17.9 LNU126 25343.1 0.137 0.103 72.4 LNU158 27433.3 0.008 0.010 118.5 LNU126 25343.4 0.101 0.120 27.4 LNU158 27433.2 0.007 0.005 94.0 LNU126 25341.1 0.093 0.472 17.1 LNU158 27432.5 0.005 0.077 43.0 LNU158 27433.3 0.193 0.007 142.3 LNU177 24762.6 0.006 0.055 69.5 LNU158 27433.2 0.145 0.000 82.0 LNU177 24764.9 0.005 0.115 30.5 LNU158 27432.5 0.129 0.011 62.9 LNU177 24764.12 0.004 0.524 17.9 LNU158 27434.1 0.087 0.526 9.9 LNU177 24765.2 0.004 0.540 11.3 LNU177 24762.6 0.142 0.012 79.1 LNU182 25384.1 0.008 0.015 102.6 LNU177 24764.9 0.127 0.003 59.2 LNU182 25384.5 0.006 0.021 68.2 LNU177 24764.12 0.103 0.280 29.4 LNU182 27521.4 0.006 0.177 57.0 LNU177 24765.2 0.098 0.191 23.3 LNU182 25384.2 0.006 0.015 55.0 LNU182 25384.2 0.177 0.063 122.7 LNU2 25713.1 0.006 0.007 67.5 LNU182 25384.1 0.156 0.022 96.2 LNU2 27842.3 0.005 0.059 37.1 LNU182 25384.5 0.155 0.047 95.5 LNU2 27842.1 0.005 0.517 35.8 LNU182 27521.4 0.136 0.225 71.0 LNU225 25991.5 0.008 0.039 109.9 LNU2 25713.1 0.140 0.006 75.9 LNU225 25991.2 0.005 0.097 22.5 LNU2 27842.1 0.127 0.182 60.4 LNU225 25991.1 0.004 0.627 9.9 LNU2 27842.3 0.103 0.058 29.2 LNU225 25991.8 0.004 0.678 8.6 LNU225 25991.5 0.169 0.013 112.9 LNU239 26284.1 0.006 0.118 47.0 LNU225 25991.8 0.134 0.177 68.3 LNU239 26281.1 0.004 0.382 18.5 LNU225 25991.3 0.115 0.264 45.3 LNU57 27854.5 0.005 0.120 37.7 LNU225 25991.2 0.105 0.071 31.6 LNU57 27855.1 0.005 0.110 30.5 LNU225 25991.1 0.097 0.169 22.6 LNU57 27854.3 0.004 0.214 18.5 LNU239 26284.1 0.111 0.154 39.4 LNU83 27681.4 0.005 0.101 27.2 LNU239 26283.2 0.104 0.056 30.3 LNU83 27684.1 0.005 0.092 23.8 LNU239 26281.1 0.102 0.034 28.0 LNU83 27685.1 0.004 0.575 16.6 LNU239 26284.2 0.086 0.431 8.2 CONT. — 0.005 — 0.0 LNU57 27854.5 0.151 0.015 90.2 LNU107 14584.9 0.012 0.000 135.8 LNU57 27854.3 0.133 0.034 67.1 LNU107 14585.2 0.007 0.067 49.4 LNU57 27855.1 0.119 0.146 49.5 LNU107 14583.8 0.005 0.598 9.0 LNU57 27851.2 0.091 0.383 14.4 LNU107 14585.5 0.005 0.488 8.4 LNU57 27852.1 0.088 0.323 10.2 LNU116 14493.6 0.009 0.144 89.3 LNU83 27685.2 0.121 0.242 52.9 LNU116 14491.5 0.009 0.003 74.9 LNU83 27681.4 0.116 0.066 46.5 LNU116 14492.5 0.008 0.003 71.9 LNU83 27685.1 0.114 0.414 43.8 LNU116 14494.5 0.007 0.202 40.7 LNU83 27684.1 0.104 0.250 30.3 LNU121 27713.4 0.015 0.000 214.6 CONT. — 0.132 — 0.0 LNU121 27713.1 0.010 0.049 104.1 LNU107 14584.9 0.254 0.000 92.8 LNU121 25642.2 0.007 0.146 42.2 LNU107 14585.2 0.157 0.116 19.2 LNU121 27713.3 0.007 0.042 39.6 LNU116 14491.5 0.191 0.020 45.3 LNU121 27711.1 0.006 0.484 16.6 LNU116 14492.5 0.178 0.032 35.2 LNU126 25343.1 0.005 0.646 9.0 LNU116 14493.6 0.177 0.130 34.3 LNU158 27433.3 0.010 0.007 109.7 LNU116 14494.5 0.146 0.513 10.8 LNU158 27432.5 0.009 0.002 88.2 LNU121 27713.4 0.302 0.000 129.5 LNU158 27433.2 0.006 0.187 28.9 LNU121 27713.1 0.221 0.148 68.0 LNU177 24764.12 0.006 0.192 26.3 LNU121 27713.3 0.189 0.103 43.2 LNU182 25384.6 0.006 0.063 27.4 LNU121 25642.2 0.181 0.269 37.7 LNU182 25384.1 0.006 0.393 18.7 LNU121 27711.1 0.146 0.459 10.7 LNU182 25384.2 0.005 0.497 9.5 LNU126 25343.1 0.145 0.561 9.9 LNU2 27842.3 0.009 0.049 76.0 LNU158 27432.5 0.223 0.000 69.6 LNU2 27845.3 0.006 0.106 27.9 LNU158 27433.3 0.216 0.018 64.2 LNU2 27842.1 0.006 0.353 21.7 LNU158 27433.2 0.151 0.438 14.9 LNU2 25713.1 0.005 0.786 7.9 LNU177 24762.6 0.154 0.335 16.9 LNU225 25991.2 0.015 0.007 206.9 LNU177 24764.12 0.139 0.715 5.3 LNU225 25991.3 0.009 0.088 90.3 LNU182 25384.6 0.139 0.656 5.6 LNU225 25991.8 0.006 0.224 20.7 LNU2 27842.3 0.220 0.023 67.2 LNU239 26281.1 0.006 0.206 26.3 LNU2 27842.1 0.165 0.250 25.4 LNU239 26283.2 0.006 0.056 25.3 LNU2 27845.3 0.162 0.280 23.1 LNU239 26284.2 0.006 0.450 19.7 LNU225 25991.2 0.297 0.008 125.7 LNU57 27852.1 0.007 0.084 48.8 LNU225 25991.3 0.206 0.142 56.2 LNU57 27851.2 0.007 0.026 47.8 LNU225 25991.8 0.155 0.226 17.7 LNU57 27854.5 0.007 0.117 33.5 LNU239 26281.1 0.156 0.176 18.1 LNU83 27685.2 0.008 0.235 59.1 LNU239 26284.2 0.153 0.408 16.1 LNU83 27685.1 0.008 0.089 56.5 LNU239 26283.2 0.139 0.709 5.5 LNU83 27681.4 0.006 0.184 25.8 LNU57 27854.5 0.179 0.112 35.6 CONT. 0.0037 LNU57 27852.1 0.172 0.171 30.2 LNU12 27371.1 0.004 0.749 3.4 LNU57 27851.2 0.171 0.158 29.6 LNU12 27372.5 0.004 0.749 3.4 LNU83 27685.2 0.208 0.139 58.1 CONT. — 0.0051 LNU83 27685.1 0.155 0.346 17.7 LNU17 13991.1 0.0068 0.04 32.2 CONT. — 0.116 — 0.0 LNU17 13991.14 0.0053 0.88 2.2 LNU17 13991.1 0.137 0.2 17.7 Table 70. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

TABLE 71 Genes showing improved plant performance at standard nitrogen growth conditions (T2 generation) Leaf Area [cm2] Gene Name Event # Average p-value % increment CONTROL — 0.520 — 0.0 LNU100 14474.3 0.909 0.052 75.0 LNU100 14474.4 0.612 0.433 17.7 LNU100 14471.4 0.547 0.605 5.3 LNU104 25033.3 0.792 0.040 52.4 LNU213 24654.4 0.962 0.029 85.0 LNU213 24653.2 0.955 0.001 83.8 LNU213 24651.1 0.658 0.045 26.6 LNU218 24783.2 1.103 0.029 112.3 LNU218 24781.7 0.689 0.037 32.6 LNU218 24781.4 0.539 0.771 3.7 LNU4 25134.1 0.737 0.008 41.7 LNU4 25134.2 0.615 0.188 18.4 LNU48 24803.2 0.798 0.007 53.5 LNU48 24802.2 0.679 0.033 30.6 LNU48 24804.4 0.672 0.056 29.2 LNU8 25063.1 0.823 0.008 58.4 LNU8 25062.2 0.780 0.032 50.0 LNU8 25063.6 0.711 0.017 36.8 LNU8 25061.2 0.537 0.772 3.3 LNU94 24833.3 0.656 0.045 26.2 LNU94 24834.4 0.542 0.751 4.3 LNU94 24834.1 0.540 0.785 3.8 CONTROL — 0.743 — 0.0 LNU1 24681.3 0.883 0.305 18.9 LNU1 24682.2 0.822 0.490 10.7 LNU1 24682.1 0.783 0.569 5.4 LNU1 24684.1 0.761 0.775 2.5 LNU133 24741.1 1.297 0.027 74.7 LNU133 24744.3 1.285 0.000 73.0 LNU175 24732.1 1.056 0.030 42.2 LNU175 24734.4 1.042 0.041 40.3 LNU175 24732.4 0.874 0.310 17.6 LNU178 14614.5 1.008 0.060 35.7 LNU178 14611.5 0.899 0.050 21.1 LNU178 14611.1 0.774 0.665 4.2 LNU215 24664.3 1.274 0.006 71.5 LNU215 24661.4 0.826 0.308 11.2 LNU24 24973.1 1.027 0.018 38.3 LNU24 24971.4 0.935 0.029 25.9 LNU24 24971.2 0.860 0.152 15.7 LNU6 24992.3 1.411 0.054 90.0 LNU6 24993.3 0.888 0.363 19.6 LNU82 24823.1 1.043 0.214 40.5 LNU9 25001.3 1.094 0.004 47.4 LNU9 25001.1 0.779 0.631 4.9 CONTROL — 0.451 — 0.0 LNU120 25463.7 0.713 0.036 58.0 LNU120 25463.3 0.645 0.006 42.8 LNU120 25463.6 0.551 0.020 22.0 LNU124 14501.7 0.732 0.000 62.2 LNU124 14501.1 0.634 0.005 40.5 LNU124 14502.7 0.526 0.283 16.4 LNU132 14102.7 0.596 0.007 32.0 LNU132 14102.9 0.546 0.025 21.0 LNU132 14101.9 0.486 0.368 7.7 LNU140 14112.7 0.666 0.098 47.5 LNU140 14111.6 0.565 0.074 25.1 LNU180 24724.3 0.805 0.000 78.4 LNU180 24723.3 0.630 0.212 39.6 LNU180 24721.4 0.508 0.401 12.5 LNU196 25534.1 0.735 0.003 62.7 LNU196 25533.1 0.536 0.064 18.8 LNU196 25533.3 0.513 0.552 13.7 LNU20 24933.2 0.653 0.075 44.8 LNU36 25562.3 0.665 0.001 47.2 LNU36 25562.4 0.540 0.131 19.5 LNU71 25853.4 0.741 0.001 64.1 LNU71 25852.4 0.510 0.187 13.0 CONTROL — 0.595 — 0.0 LNU1 24681.3 0.709 0.020 19.2 LNU110 24952.3 0.665 0.293 11.8 LNU110 24953.3 0.636 0.554 6.9 LNU175 24733.4 0.921 0.050 54.8 LNU175 24732.2 0.777 0.288 30.7 LNU19 25151.1 0.781 0.024 31.3 LNU215 24663.4 0.833 0.092 40.0 LNU27 24873.1 0.882 0.005 48.4 LNU44 24924.3 0.871 0.059 46.4 LNU54 24903.5 0.780 0.169 31.1 LNU79 24884.4 0.866 0.000 45.6 LNU79 24881.1 0.810 0.007 36.3 LNU79 24884.3 0.696 0.240 17.0 CONTROL — 0.674 — 0.0 LNU109 24891.2 1.109 0.005 64.4 LNU109 24892.6 0.925 0.007 37.1 LNU109 24892.5 0.848 0.274 25.7 LNU109 24891.5 0.790 0.157 17.2 LNU110 24952.1 1.232 0.008 82.7 LNU110 24954.1 1.043 0.005 54.6 LNU110 24953.2 0.971 0.000 44.0 LNU110 24952.3 0.971 0.064 44.0 LNU110 24954.3 0.816 0.036 21.0 LNU133 24741.2 1.252 0.000 85.6 LNU133 24741.1 1.225 0.000 81.7 LNU133 24744.3 1.178 0.000 74.7 LNU133 24742.2 0.924 0.057 37.0 LNU133 24744.2 0.886 0.033 31.4 LNU19 25151.1 1.249 0.001 85.2 LNU19 25153.3 0.867 0.184 28.5 LNU19 25151.11 0.689 0.740 2.1 LNU27 24873.4 1.248 0.017 85.1 LNU27 24871.4 0.847 0.076 25.5 LNU27 24873.1 0.750 0.098 11.2 LNU44 24922.3 1.096 0.008 62.6 LNU44 24924.3 0.924 0.016 37.0 LNU44 24923.1 0.801 0.040 18.7 LNU54 24903.5 1.320 0.005 95.8 LNU54 24902.4 1.016 0.094 50.6 LNU54 24901.2 0.862 0.242 27.8 LNU6 24994.5 1.197 0.051 77.4 LNU6 24992.3 1.154 0.013 71.0 LNU6 24994.1 0.800 0.326 18.6 LNU6 24994.2 0.772 0.294 14.5 LNU79 24882.2 1.111 0.005 64.8 LNU79 24881.1 1.064 0.014 57.8 LNU79 24884.4 1.023 0.070 51.7 LNU79 24883.2 0.958 0.079 42.1 LNU79 24884.3 0.910 0.051 34.9 CONTROL — 0.559 — 0.0 LNU109 24892.8 1.054 0.000 88.6 LNU109 24891.5 0.876 0.050 56.8 LNU109 24891.2 0.860 0.022 53.8 LNU143 25975.2 0.731 0.020 30.8 LNU143 25972.1 0.719 0.187 28.7 LNU143 25975.3 0.619 0.264 10.8 LNU154 14604.7 0.890 0.003 59.3 LNU154 14601.6 0.747 0.029 33.6 LNU154 14604.6 0.695 0.143 24.3 LNU154 14602.8 0.661 0.147 18.3 LNU196 25532.2 1.107 0.041 98.0 LNU196 25534.1 0.910 0.002 62.8 LNU196 25531.2 0.644 0.401 15.2 LNU207 24642.5 1.002 0.017 79.2 LNU207 24642.4 0.734 0.031 31.3 LNU207 24644.18 0.653 0.190 16.7 LNU207 24644.13 0.593 0.657 6.0 LNU288 14564.9 0.770 0.011 37.8 LNU288 14562.12 0.740 0.130 32.4 LNU288 14562.7 0.669 0.149 19.7 LNU288 14562.9 0.647 0.157 15.8 LNU288 14562.1 0.629 0.249 12.6 LNU50 26024.2 0.845 0.009 51.2 LNU50 26025.4 0.731 0.051 30.8 LNU50 26023.2 0.598 0.452 7.0 LNU52 25723.2 0.891 0.002 59.4 LNU52 25721.3 0.878 0.031 57.1 LNU52 25721.4 0.735 0.149 31.5 CONTROL — 0.682 — 0.0 LNU154 14601.6 0.842 0.479 23.4 LNU207 24642.5 1.017 0.003 49.0 LNU207 24642.4 0.762 0.283 11.7 LNU52 25721.4 0.962 0.049 41.1 LNU52 25721.1 0.841 0.089 23.3 LNU52 25723.1 0.796 0.166 16.7 LNU69 14571.1 0.857 0.065 25.6 LNU69 14572.8 0.721 0.699 5.8 CONTROL — 0.671 — 0.0 LNU150 24843.5 0.871 0.043 29.8 LNU150 24842.9 0.819 0.046 22.1 LNU150 24841.9 0.792 0.226 17.9 LNU150 24843.9 0.703 0.750 4.7 LNU232 26003.7 0.797 0.151 18.7 LNU242 25474.1 0.929 0.011 38.4 LNU242 25473.1 0.807 0.260 20.2 LNU242 25471.1 0.727 0.448 8.3 LNU76 26421.2 0.849 0.257 26.5 LNU76 26422.2 0.709 0.692 5.6 LNU95 13985.15 0.775 0.359 15.4 LNU95 13985.11 0.773 0.220 15.2 CONTROL — 0.673 — 0.0 LNU118 14013.8 0.865 0.061 28.5 LNU118 14013.6 0.858 0.008 27.3 LNU118 14012.15 0.830 0.176 23.3 LNU118 14012.12 0.755 0.105 12.1 LNU118 14012.14 0.747 0.298 11.0 LNU150 24842.9 1.049 0.004 55.7 LNU150 24841.9 0.886 0.001 31.6 LNU150 24841.6 0.706 0.577 4.8 LNU179 24632.7 0.863 0.063 28.1 LNU179 24631.7 0.822 0.051 22.1 LNU179 24631.6 0.724 0.338 7.5 LNU179 24632.5 0.721 0.567 7.1 LNU232 26001.5 0.850 0.038 26.2 LNU232 26003.3 0.728 0.265 8.1 LNU232 26003.6 0.693 0.747 2.8 LNU235 26184.4 1.120 0.011 66.3 LNU235 26184.2 0.945 0.003 40.3 LNU235 26185.2 0.930 0.006 38.1 LNU235 26182.1 0.700 0.566 3.9 LNU242 25474.1 0.813 0.050 20.7 LNU288 14563.9 1.152 0.001 71.1 LNU288 14562.1 0.970 0.007 44.0 LNU288 14564.9 0.863 0.189 28.2 LNU288 14563.6 0.799 0.109 18.7 LNU288 14562.7 0.768 0.398 14.1 LNU76 26421.2 0.775 0.254 15.0 LNU76 26422.2 0.730 0.443 8.4 LNU76 26425.1 0.723 0.524 7.3 LNU76 26423.1 0.721 0.490 7.1 LNU95 13985.16 1.140 0.004 69.3 LNU95 13985.15 1.040 0.019 54.4 LNU95 13985.12 0.863 0.019 28.2 LNU95 13985.19 0.742 0.339 10.1 CONTROL — 0.587 — 0.0 LNU101 27635.1 0.700 0.037 19.3 LNU101 27632.1 0.693 0.073 18.0 LNU101 27632.7 0.630 0.160 7.3 LNU128 26515.3 0.812 0.011 38.3 LNU128 26515.2 0.700 0.303 19.3 LNU192 28315.2 0.682 0.177 16.2 LNU192 28313.2 0.609 0.756 3.8 LNU206 27621.1 0.621 0.678 5.8 LNU211 24771.1 0.785 0.066 33.7 LNU282 27563.3 0.811 0.008 38.2 LNU69 14571.1 0.824 0.009 40.3 LNU69 14573.5 0.681 0.042 16.0 LNU69 14572.9 0.629 0.134 7.2 LNU75 27572.1 0.820 0.003 39.6 LNU75 27572.2 0.691 0.164 17.7 CONTROL — 0.552 — 0.0 LNU101 27632.5 0.745 0.060 34.9 LNU118 14013.6 0.692 0.094 25.3 LNU118 14012.15 0.649 0.267 17.5 LNU118 14013.9 0.570 0.713 3.2 LNU206 27621.2 0.776 0.001 40.5 LNU206 27621.1 0.644 0.120 16.7 LNU249 26153.1 0.883 0.034 59.9 LNU282 27563.1 0.724 0.117 31.1 LNU282 27565.2 0.611 0.277 10.7 LNU288 14563.9 0.866 0.002 57.0 LNU288 14564.8 0.854 0.000 54.7 LNU288 14562.9 0.730 0.072 32.2 LNU288 14562.7 0.643 0.244 16.5 LNU288 14563.6 0.600 0.538 8.7 LNU75 27571.4 0.782 0.049 41.7 LNU75 27572.3 0.743 0.085 34.5 LNU75 27572.2 0.691 0.169 25.1 LNU75 27571.2 0.641 0.112 16.1 CONTROL — 0.642 — 0.0 LNU11 28204.3 0.685 0.490 6.6 LNU11 28204.1 0.676 0.655 5.2 LNU14 27824.2 0.763 0.613 18.8 LNU183 24863.12 1.132 0.001 76.2 LNU183 24863.1 0.922 0.003 43.6 LNU183 24865.1 0.908 0.018 41.3 LNU183 24864.6 0.736 0.125 14.5 LNU201 28223.1 0.662 0.688 3.1 LNU268 26044.2 0.758 0.210 18.0 LNU268 26045.1 0.719 0.210 11.9 CONTROL — 0.542 — 0.0 LNU11 28204.1 0.672 0.073 24.1 LNU11 28205.1 0.652 0.233 20.4 LNU11 28205.2 0.652 0.099 20.4 LNU11 28203.2 0.615 0.226 13.6 LNU11 28204.3 0.603 0.316 11.4 LNU112 28212.4 0.688 0.070 27.1 LNU112 28212.1 0.605 0.413 11.8 LNU14 27821.4 0.673 0.156 24.3 LNU14 27821.3 0.671 0.217 24.0 LNU14 27823.2 0.638 0.158 17.8 LNU183 24865.1 1.352 0.000 149.7 LNU183 24863.12 1.265 0.011 133.6 LNU183 24863.1 1.237 0.000 128.4 LNU183 24864.6 1.231 0.000 127.3 LNU183 24864.7 0.586 0.464 8.2 LNU191 28325.4 0.740 0.061 36.6 LNU191 28324.2 0.718 0.046 32.6 LNU191 28325.3 0.664 0.080 22.5 LNU191 28323.1 0.653 0.442 20.6 LNU201 28222.2 0.891 0.036 64.5 LNU201 28223.3 0.616 0.301 13.7 LNU201 28221.3 0.561 0.783 3.6 LNU268 26043.4 0.715 0.025 32.0 LNU268 26041.4 0.685 0.049 26.5 LNU268 26041.6 0.588 0.639 8.6 LNU268 26045.1 0.578 0.753 6.8 CONTROL — 0.441 — 0.0 LNU107 14585.5 0.576 0.422 30.6 LNU107 14583.8 0.573 0.226 29.9 LNU107 14584.9 0.534 0.315 21.0 LNU116 14494.5 0.616 0.067 39.7 LNU116 14493.6 0.594 0.075 34.7 LNU116 14492.9 0.539 0.011 22.2 LNU116 14492.5 0.530 0.156 20.3 LNU121 25642.2 0.892 0.002 102.2 LNU121 27713.4 0.708 0.004 60.6 LNU121 27713.1 0.689 0.064 56.1 LNU121 27711.1 0.666 0.064 50.9 LNU126 25343.3 0.680 0.000 54.1 LNU126 25345.1 0.656 0.054 48.8 LNU126 25343.1 0.618 0.135 40.0 LNU158 27433.3 0.633 0.045 43.5 LNU158 27433.2 0.556 0.195 26.1 LNU158 27432.5 0.520 0.523 17.8 LNU177 24762.6 0.626 0.100 41.9 LNU177 24765.2 0.531 0.253 20.4 LNU177 24764.9 0.500 0.348 13.4 LNU182 25384.5 0.581 0.034 31.8 LNU182 27521.4 0.553 0.394 25.3 LNU182 25384.1 0.529 0.310 20.0 LNU182 25384.2 0.497 0.219 12.7 LNU2 25713.1 0.618 0.057 40.0 LNU2 27842.1 0.519 0.628 17.6 LNU2 27842.3 0.497 0.464 12.7 LNU225 25991.5 0.547 0.210 24.0 LNU225 25991.2 0.487 0.532 10.3 LNU239 26284.1 0.652 0.019 47.7 LNU239 26283.2 0.527 0.219 19.4 LNU239 26281.1 0.472 0.550 6.9 LNU57 27854.3 0.491 0.236 11.3 LNU83 27684.1 0.490 0.592 11.0 LNU83 27681.4 0.472 0.584 7.1 CONTROL — 0.297 — 0.0 LNU107 14584.9 0.620 0.002 108.6 LNU107 14585.2 0.527 0.063 77.1 LNU107 14585.5 0.435 0.088 46.4 LNU107 14583.8 0.370 0.175 24.3 LNU107 14583.1 0.344 0.429 15.7 LNU116 14492.5 0.627 0.035 110.8 LNU116 14493.6 0.482 0.085 62.1 LNU116 14491.5 0.470 0.086 57.9 LNU116 14494.5 0.401 0.051 34.8 LNU116 14492.9 0.365 0.320 22.8 LNU121 27713.4 0.901 0.001 202.9 LNU121 27713.1 0.656 0.008 120.7 LNU121 27713.3 0.544 0.002 83.0 LNU121 25642.2 0.534 0.012 79.7 LNU121 27711.1 0.494 0.080 66.1 LNU126 25343.1 0.564 0.001 89.8 LNU126 25343.3 0.435 0.286 46.3 LNU126 25343.4 0.366 0.124 23.2 LNU126 25345.1 0.365 0.150 22.7 LNU158 27433.3 0.707 0.011 137.7 LNU158 27432.5 0.696 0.000 134.0 LNU158 27433.2 0.584 0.020 96.3 LNU158 27434.5 0.338 0.249 13.7 LNU158 27434.1 0.310 0.798 4.3 LNU177 24762.6 0.434 0.130 46.1 LNU177 24763.6 0.352 0.452 18.5 LNU177 24764.12 0.348 0.287 17.1 LNU182 25384.1 0.515 0.026 73.2 LNU182 25384.6 0.510 0.161 71.7 LNU182 25384.2 0.451 0.001 51.6 LNU182 25384.5 0.353 0.448 18.7 LNU182 27521.4 0.328 0.531 10.3 LNU2 27845.3 0.556 0.109 87.0 LNU2 25713.1 0.522 0.023 75.5 LNU2 27842.3 0.503 0.001 69.3 LNU2 27842.1 0.453 0.019 52.4 LNU2 27845.2 0.352 0.351 18.4 LNU225 25991.2 0.762 0.000 156.2 LNU225 25991.3 0.582 0.016 95.9 LNU225 25991.1 0.473 0.147 59.1 LNU225 25991.8 0.472 0.067 58.9 LNU225 25991.5 0.331 0.343 11.2 LNU239 26284.2 0.503 0.042 69.2 LNU239 26283.2 0.491 0.014 65.2 LNU239 26281.1 0.475 0.029 59.7 LNU239 26284.1 0.430 0.145 44.6 LNU239 26283.3 0.422 0.161 41.9 LNU57 27852.1 0.508 0.006 71.0 LNU57 27851.2 0.472 0.001 58.6 LNU57 27854.5 0.330 0.420 11.1 LNU83 27685.1 0.554 0.099 86.4 LNU83 27685.2 0.510 0.000 71.7 LNU83 27681.4 0.399 0.286 34.3 LNU83 27682.1 0.368 0.168 24.0 LNU83 27684.1 0.336 0.653 12.9 CONTROL — 0.467 0.0 LNU129 27501.2 0.636 <0.1 36.3 LNU129 27502.4 0.527 <0.4 13.0 LNU129 27504.2 0.687 <0.1 47.1 LNU129 27504.3 0.897 <0.1 92.2 LNU147 27513.2 0.654 <0.1 40.2 LNU147 27514.1 0.540 <0.4 15.6 LNU147 27514.2 0.536 <0.4 14.8 LNU153 24851.3 0.490 <0.7 5.0 LNU189 26382.3 0.626 <0.1 34.0 LNU189 26382.4 0.597 <0.1 28.0 LNU189 26383.1 0.666 <0.1 42.6 LNU189 26385.1 0.524 <0.4 12.3 LNU189 26385.2 0.513 <0.7 9.9 LNU219 27461.1 0.784 <0.1 67.9 LNU219 27462.1 0.773 <0.1 65.6 LNU219 27462.2 0.644 <0.1 38.0 LNU219 27464.1 0.499 <0.7 7.0 LNU256 26212.3 0.650 <0.1 39.3 LNU256 26213.1 0.630 <0.1 34.9 LNU256 26214.1 0.649 <0.1 39.0 LNU257 26254.1 0.522 <0.4 11.9 LNU257 26254.3 0.883 <0.1 89.1 LNU257 26254.7 0.589 <0.2 26.1 LNU257 26255.3 0.589 <0.2 26.1 LNU261 27403.2 0.646 <0.1 38.3 LNU261 27405.1 0.646 <0.1 38.5 LNU33 25552.2 0.679 <0.1 45.4 LNU33 25553.2 0.592 <0.2 26.9 LNU33 25555.1 0.503 <0.7 7.9 LNU35 27421.2 0.574 <0.2 22.9 LNU35 27422.1 0.903 <0.1 93.4 LNU35 27423.3 0.615 <0.1 31.8 LNU35 27424.3 0.584 <0.2 25.1 LNU35 27424.4 0.607 <0.1 30.1 LNU50 26022.1 0.725 <0.1 55.3 LNU50 26023.2 0.604 <0.1 29.4 LNU50 26023.3 0.557 <0.2 19.2 LNU50 26024.1 0.730 <0.1 56.3 LNU50 26025.3 0.859 <0.1 84.0 LNU70 25313.1 0.735 <0.1 57.5 LNU70 25313.2 0.657 <0.1 40.8 Table 71.

TABLE 72 Genes showing improved plant performance at standard nitrogen growth conditions (T1 generation) Plant Biomass Plant Biomass Fresh Weight [gr.] Dry Weight [gr.] Gene % Gene % Name Ave. p-value incr. Name Ave. p-value incr. CONT. 0.160 — 0.0 CONT. 0.008 — 0.0 LNU121 0.176 0.305 9.8 LNU121 0.009 0.243 19.5 LNU150 0.160 0.987 0.2 LNU154 0.008 0.489 11.3 LNU154 0.166 0.808 4.0 CONT. 0.005 — 0.0 CONT. 0.118 — 0.0 LNU275 0.010 0.005 85.2 LNU275 0.189 0.022 60.3 LNU57 0.006 0.574 10.3 LNU57 0.124 0.697 5.1 LNU64 0.006 0.254 14.1 LNU64 0.127 0.509 7.6 LNU83 0.006 0.295 18.9 LNU83 0.132 0.385 12.1 CONT. 0.005 — 0.0 CONT. 0.110 — 0.0 LNU59 0.005 0.560 12.0 LNU176 0.115 0.670 4.5 LNU60 0.006 0.553 12.5 LNU247 0.112 0.884 1.6 LNU284 0.112 0.941 1.5 CONT. 0.128 — 0.0 LNU59 0.134 0.717 5.0 LNU60 0.135 0.703 5.5 Table 72. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

TABLE 73 Genes showing improved plant performance at standard nitrogen growth conditions (T1 generation) Leaf Area [cm2] Gene Name Time Point Average p-value % increment CONTROL Leaf_Area_TP2 0.328 — 0.0 LNU154 Leaf_Area_TP2 0.334 0.886 1.6 CONTROL Leaf_Area_TP3 0.629 — 0.0 LNU121 Leaf_Area_TP3 0.649 0.667 3.1 CONTROL Leaf_Area_TP2 0.289 — 0.0 LNU127 Leaf_Area_TP2 0.295 0.783 2.3 LNU275 Leaf_Area_TP2 0.492 0.000 70.5 LNU32 Leaf_Area_TP2 0.309 0.519 7.1 LNU57 Leaf_Area_TP2 0.313 0.309 8.4 LNU58 Leaf_Area_TP2 0.305 0.421 5.8 LNU83 Leaf_Area_TP2 0.381 0.032 32.1 CONTROL Leaf_Area_TP3 0.626 — 0.0 LNU275 Leaf_Area_TP3 0.981 0.004 56.7 LNU57 Leaf_Area_TP3 0.691 0.354 10.3 LNU64 Leaf_Area_TP3 0.630 0.935 0.7 LNU83 Leaf_Area_TP3 0.781 0.069 24.7 CONTROL Leaf_Area_TP2 0.298 — 0.0 LNU59 Leaf_Area_TP2 0.302 0.885 1.4 CONTROL Leaf_Area_TP3 0.606 — 0.0 LNU59 Leaf_Area_TP3 0.631 0.619 4.1 Table 73.

The genes listed in Tables 74 and 75 improved plant NUE when grown at standard nitrogen concentration levels. These genes produced larger root biomass (root length and root coverage) when grown under standard nitrogen growth conditions, compared to control plants. Plants producing larger root biomass have better possibilities to absorb larger amount of nitrogen from soil. The genes were cloned under the regulation of a constitutive promoter (At6669) or root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one tissue culture assay resulting in positive results as well. Event with p-value <0.1 was considered statistically significant

TABLE 74 Genes showing improved root performance at standard nitrogen growth conditions (T2 generation) Gene Roots Length [cm] Gene Roots Coverage [cm2] Name Event # Ave. p-value % incr. Name Event # Ave. p-value % incr. CONT. — 4.849 — 0.0 CONT. — 3.976 — 0.0 LNU100 14474.3 6.391 0.001 31.8 LNU100 14474.3 5.804 0.076 46.0 LNU100 14471.4 6.031 0.073 24.4 LNU100 14474.4 5.605 0.215 41.0 LNU100 14474.4 5.910 0.082 21.9 LNU100 14471.4 5.036 0.150 26.7 LNU100 14473.1 5.412 0.078 11.6 LNU104 25033.3 5.092 0.128 28.1 LNU100 14473.3 5.137 0.473 5.9 LNU213 24654.4 6.150 0.072 54.7 LNU104 25033.3 6.109 0.003 26.0 LNU213 24653.2 5.740 0.034 44.4 LNU104 25032.1 5.255 0.247 8.4 LNU213 24651.1 4.940 0.159 24.3 LNU104 25033.1 5.022 0.613 3.6 LNU218 24783.2 7.745 0.049 94.8 LNU104 25032.2 4.979 0.747 2.7 LNU218 24781.2 4.894 0.179 23.1 LNU213 24653.2 6.170 0.004 27.2 LNU218 24781.7 4.617 0.254 16.1 LNU213 24654.4 6.029 0.014 24.3 LNU218 24781.4 4.145 0.714 4.3 LNU213 24651.1 5.610 0.111 15.7 LNU4 25134.1 4.657 0.201 17.1 LNU213 24653.1 5.144 0.485 6.1 LNU48 24802.2 4.922 0.256 23.8 LNU218 24783.2 7.188 0.000 48.2 LNU48 24804.4 4.630 0.443 16.5 LNU218 24781.1 5.595 0.039 15.4 LNU48 24803.2 4.430 0.384 11.4 LNU218 24781.7 5.435 0.155 12.1 LNU8 25063.1 7.354 0.004 85.0 LNU218 24781.4 5.290 0.210 9.1 LNU8 25062.2 5.008 0.068 26.0 LNU218 24781.2 5.196 0.253 7.2 LNU8 25063.6 4.121 0.730 3.7 LNU4 25131.1 6.021 0.008 24.2 LNU94 24833.1 4.236 0.661 6.5 LNU4 25134.1 5.680 0.098 17.1 LNU94 24834.4 4.130 0.709 3.9 LNU4 25134.2 5.462 0.041 12.6 CONT. — 5.584 — 0.0 LNU4 25133.3 5.018 0.587 3.5 LNU1 24682.2 7.395 0.107 32.4 LNU48 24804.4 5.956 0.010 22.8 LNU1 24682.1 6.727 0.071 20.5 LNU48 24802.2 5.586 0.106 15.2 LNU1 24684.1 6.661 0.177 19.3 LNU48 24803.2 5.049 0.544 4.1 LNU1 24681.1 6.270 0.284 12.3 LNU8 25063.1 6.763 0.000 39.5 LNU133 24744.3 9.891 0.000 77.1 LNU8 25062.2 6.296 0.001 29.8 LNU133 24741.1 9.192 0.066 64.6 LNU8 25063.6 5.123 0.416 5.7 LNU132 24741.2 6.714 0.087 20.2 LNU8 25062.1 5.016 0.610 3.5 LNU175 24732.1 9.540 0.038 70.8 LNU94 24834.4 5.557 0.058 14.6 LNU175 24732.4 9.071 0.011 62.5 LNU94 24833.3 5.351 0.233 10.4 LNU175 24734.4 8.342 0.004 49.4 CONT. — 6.645 — 0.0 LNU175 24731.2 5.955 0.657 6.6 LNU1 24682.2 6.883 0.409 3.6 LNU178 14614.5 8.913 0.010 59.6 LNU1 24684.1 6.833 0.350 2.8 LNU178 14611.5 7.578 0.133 35.7 LNU133 24744.3 6.958 0.328 4.7 LNU178 14612.1 6.454 0.303 15.6 LNU175 24732.1 7.028 0.152 5.8 LNU178 14611.4 5.776 0.777 3.4 LNU175 24732.4 6.739 0.677 1.4 LNU215 24664.3 9.619 0.027 72.3 LNU178 14614.5 7.100 0.133 6.8 LNU215 24661.4 7.432 0.016 33.1 LNU215 24664.2 6.776 0.643 2.0 LNU215 24663.4 6.228 0.402 11.5 LNU215 24664.3 6.739 0.765 1.4 LNU215 24664.2 5.760 0.756 3.2 CONT. — 5.816 — 0.0 LNU24 24971.4 8.367 0.080 49.8 LNU120 25463.7 7.237 0.001 24.4 LNU24 24973.1 7.707 0.151 38.0 LNU120 25463.6 6.531 0.009 12.3 LNU6 24992.3 9.043 0.105 61.9 LNU120 25463.3 6.304 0.096 8.4 LNU6 24993.3 7.325 0.282 31.2 LNU124 14502.1 6.609 0.003 13.6 LNU82 24823.1 7.225 0.154 29.4 LNU124 14502.7 6.545 0.113 12.5 LNU82 24824.3 5.882 0.638 5.4 LNU124 14501.1 6.332 0.094 8.9 LNU9 25001.3 8.110 0.025 45.2 LNU124 14501.7 5.964 0.685 2.5 LNU9 25001.1 7.174 0.035 28.5 LNU132 14102.9 6.457 0.057 11.0 LNU9 25001.2 6.256 0.317 12.0 LNU132 14102.7 6.113 0.611 5.1 CONT. — 4.531 — 0.0 LNU140 14114.8 6.579 0.061 13.1 LNU120 25463.7 7.868 0.038 73.6 LNU140 14111.6 6.576 0.004 13.1 LNU120 25463.6 5.970 0.030 31.8 LNU140 14112.7 5.926 0.577 1.9 LNU120 25463.3 5.164 0.181 14.0 LNU180 24723.3 6.266 0.142 7.7 LNU124 14502.7 5.914 0.076 30.5 LNU180 24724.3 6.232 0.321 7.1 LNU124 14501.7 5.595 0.192 23.5 LNU180 24724.1 6.204 0.096 6.7 LNU124 14502.1 5.257 0.081 16.0 LNU196 25534.1 5.957 0.581 2.4 LNU124 14501.1 5.079 0.170 12.1 LNU196 25533.3 5.955 0.740 2.4 LNU132 14102.7 5.508 0.146 21.6 LNU20 24933.2 6.550 0.079 12.6 LNU132 14102.9 5.228 0.247 15.4 LNU20 24933.4 6.103 0.334 4.9 LNU140 14111.6 5.840 0.083 28.9 LNU36 25562.3 7.052 0.001 21.2 LNU140 14112.7 5.539 0.146 22.2 LNU36 25562.4 6.098 0.448 4.9 LNU140 14114.8 5.460 0.025 20.5 LNU71 25852.5 5.985 0.623 2.9 LNU180 24724.3 6.600 0.013 45.7 CONT. — 5.715 — 0.0 LNU180 24723.3 5.650 0.177 24.7 LNU1 24684.1 5.994 0.624 4.9 LNU180 24721.4 4.990 0.306 10.1 LNU1 24682.1 5.985 0.700 4.7 LNU180 24724.1 4.848 0.394 7.0 LNU110 24953.2 6.472 0.204 13.2 LNU196 25534.1 5.798 0.172 28.0 LNU110 24954.3 6.240 0.371 9.2 LNU196 25533.3 4.974 0.596 9.8 LNU110 24953.3 5.887 0.761 3.0 LNU196 25533.1 4.907 0.537 8.3 LNU175 24733.4 7.017 0.056 22.8 LNU20 24933.2 6.361 0.076 40.4 LNU175 24732.1 6.599 0.155 15.5 LNU20 24932.4 5.171 0.277 14.1 LNU175 24734.4 6.338 0.297 10.9 LNU20 24933.4 4.880 0.392 7.7 LNU19 25151.11 5.917 0.721 3.5 LNU36 25562.3 7.451 0.014 64.4 LNU215 24664.2 6.822 0.089 19.4 LNU36 25562.4 5.452 0.174 20.3 LNU215 24663.3 6.562 0.164 14.8 LNU71 25853.4 6.607 0.024 45.8 LNU215 24663.4 6.429 0.239 12.5 CONT. — 5.186 — 0.0 LNU215 24661.4 6.327 0.285 10.7 LNU1 24681.3 6.080 0.219 17.2 LNU27 24873.1 6.861 0.096 20.0 LNU110 24952.3 5.702 0.579 10.0 LNU27 24871.4 6.399 0.243 12.0 LNU175 24733.4 9.339 0.011 80.1 LNU27 24873.4 5.879 0.794 2.9 LNU175 24732.2 6.572 0.148 26.7 LNU44 24923.3 6.618 0.168 15.8 LNU175 24734.4 5.788 0.436 11.6 LNU44 24924.2 6.437 0.234 12.6 LNU175 24732.1 5.692 0.490 9.8 LNU44 24922.3 6.341 0.322 11.0 LNU19 25151.1 5.793 0.383 11.7 LNU44 24923.1 5.999 0.607 5.0 LNU215 24663.4 7.608 0.035 46.7 LNU54 24901.2 7.145 0.047 25.0 LNU215 24664.2 6.954 0.131 34.1 LNU54 24902.4 7.103 0.062 24.3 LNU215 24663.3 5.781 0.411 11.5 LNU54 24902.7 6.053 0.543 5.9 LNU215 24663.1 5.562 0.795 7.3 LNU54 24903.3 5.999 0.668 5.0 LNU27 24873.1 8.055 0.022 55.3 LNU54 24903.5 5.976 0.679 4.6 LNU27 24873.4 5.906 0.364 13.9 LNU79 24881.1 7.091 0.049 24.1 LNU27 24871.4 5.882 0.322 13.4 LNU79 24882.2 6.898 0.082 20.7 LNU44 24924.2 6.515 0.098 25.6 LNU79 24883.2 6.280 0.322 9.9 LNU44 24924.3 6.346 0.246 22.4 LNU79 24884.4 6.016 0.595 5.3 LNU44 24923.3 6.219 0.267 19.9 CONT. — 6.033 — 0.0 LNU44 24922.3 5.394 0.779 4.0 LNU109 24892.6 6.662 0.003 10.4 LNU54 24902.4 7.593 0.092 46.4 LNU109 24892.8 6.584 0.089 9.1 LNU54 24901.2 7.095 0.160 36.8 LNU109 24892.5 6.471 0.091 7.3 LNU54 24903.5 6.720 0.141 29.6 LNU109 24891.5 6.398 0.149 6.0 LNU54 24903.3 6.233 0.284 20.2 LNU109 24891.2 6.168 0.624 2.2 LNU79 24881.1 9.394 0.001 81.1 LNU110 24952.1 7.116 0.032 17.9 LNU79 24884.4 6.787 0.061 30.9 LNU110 24952.3 6.584 0.252 9.1 LNU79 24884.3 5.863 0.407 13.1 LNU110 24954.1 6.477 0.388 7.4 LNU79 24882.2 5.824 0.552 12.3 LNU110 24953.2 6.476 0.414 7.3 CONT. — 5.925 — 0.0 LNU110 24954.3 6.318 0.252 4.7 LNU109 24892.6 9.651 0.001 62.9 LNU133 24744.3 7.193 0.003 19.2 LNU109 24892.5 8.357 0.129 41.1 LNU133 24741.2 6.655 0.043 10.3 LNU10 24891.2 7.582 0.064 28.0 LNU133 24741.1 6.592 0.059 9.3 LNU109 24891.5 7.440 0.090 25.6 LNU133 24742.2 6.248 0.133 3.6 LNU109 24892.8 6.366 0.511 7.5 LNU19 25151.1 6.386 0.125 5 .9 LNU110 24952.1 10.431 0.010 76.1 LNU27 24873.1 7.085 0.070 17.4 LNU110 24954.1 9.168 0.016 54.7 LNU27 24871.4 7.029 0.003 16.5 LNU110 24953.2 8.763 0.119 47.9 LNU27 24873.4 6.424 0.115 6.5 LNU110 24954.3 8.415 0.020 42.0 LNU27 24872.3 6.125 0.692 1.5 LNU110 24952.3 8.298 0.094 40.1 LNU44 24922.3 6.695 0.003 11.0 LNU133 24744.3 9.969 0.000 68.3 LNU44 24923.3 6.472 0.305 7.3 LNU133 24741.2 9.419 0.006 59.0 LNU44 24924.3 6.113 0.701 1.3 LNU133 24741.1 9.029 0.014 52.4 LNU54 24901.2 6.844 0.049 13.4 LNU133 24742.2 8.023 0.041 35.4 LNU54 24903.5 6.790 0.005 12.5 LNU133 24744.2 7.532 0.080 27.1 LNU54 24902.4 6.782 0.066 12.4 LNU19 25151.1 9.075 0.003 53.2 LNU54 24903.3 6.624 0.045 9.8 LNU19 25153.3 7.527 0.201 27.0 LNU54 24902.7 6.298 0.398 4.4 LNU19 25151.11 7.438 0.043 25.6 LNU6 24994.2 6.782 0.062 12.4 LNU27 24873.4 8.650 0.067 46.0 LNU6 24992.3 6.759 0.044 12.0 LNU27 24871.4 8.011 0.092 35.2 LNU6 24994.5 6.673 0.102 10.6 LNU27 24873.1 7.767 0.045 31.1 LNU6 24993.3 6.261 0.154 3.8 LNU44 24922.3 10.244 0.000 72.9 LNU79 24884.4 6.952 0.014 15.2 LNU44 24923.3 8.210 0.130 38.6 LNU79 24881.1 6.550 0.233 8.6 LNU44 24924.3 6.559 0.435 10.7 LNU79 24882.2 6.508 0.140 7.9 LNU44 24923.1 6.379 0.492 7.7 LNU79 24883.2 6.422 0.119 6.4 LNU54 24903.5 9.523 0.016 60.7 CONT. — 6.265 — 0.0 LNU54 24902.4 7.707 0.237 30.1 LNU109 24892.8 6.456 0.444 3.1 LNU54 24901.2 7.417 0.368 25.2 LNU143 25975.3 6.422 0.445 2.5 LNU54 24903.3 6.587 0.292 11.2 LNU154 14601.6 6.582 0.290 5.1 LNU6 24992.3 9.573 0.029 61.6 LNU196 25534.1 6.487 0.491 3.5 LNU6 24994.5 9.480 0.098 60.0 LNU207 24642.5 6.853 0.030 9.4 LNU6 24994.2 8.627 0.028 45.6 LNU207 24641.1 6.636 0.131 5.9 LNU6 24994.1 6.376 0.617 7.6 LNU50 26023.2 6.670 0.171 6.5 LNU79 24884.4 9.253 0.084 56.2 LNU50 26024.2 6.465 0.315 3.2 LNU79 24881.1 8.970 0.067 51.4 LNU52 25723.2 6.373 0.746 1.7 LNU79 24883.2 8.450 0.010 42.6 CONT. — 5.225 — 0.0 LNU79 24884.3 8.381 0.068 41.5 LNU143 25971.2 6.542 0.010 25.2 LNU79 24882.2 8.338 0.007 40.7 LNU143 25975.3 6.302 0.007 20.6 CONT. — 5.283 — 0.0 LNU143 25975.2 5.975 0.034 14.4 LNU109 24892.8 7.899 0.001 49.5 LNU143 25971.5 5.900 0.059 12.9 LNU109 24891.5 7.630 0.001 44.4 LNU143 25972.1 5.684 0.234 8.8 LNU143 25975.2 6.615 0.035 25.2 LNU154 14601.6 6.510 0.005 24.6 LNU143 25972.1 5.812 0.490 10.0 LNU207 24641.1 6.531 0.170 25.0 LNU143 25975.3 5.802 0.294 9.8 LNU207 24642.5 6.154 0.029 17.8 LNU154 14604.7 7.402 0.014 40.1 LNU207 24642.4 5.651 0.193 8.2 LNU154 14601.6 6.345 0.203 20.1 LNU211 24771.1 6.217 0.015 19.0 LNU196 25532.2 7.364 0.294 39.4 LNU211 24771.3 5.368 0.648 2.7 LNU196 25534.1 6.774 0.009 28.2 LNU52 25723.1 6.492 0.004 24.3 LNU207 24642.5 7.232 0.151 36.9 LNU52 25721.2 5.400 0.761 3.4 LNU207 24642.4 6.473 0.126 22.5 LNU52 25721.1 5.342 0.673 2.3 LNU207 24644.18 6.146 0.444 16.3 LNU69 14571.1 6.159 0.119 17.9 LNU207 24644.13 5.800 0.264 9.8 LNU69 14573.3 5.824 0.070 11.5 LNU207 24641.1 5.667 0.688 7.3 LNU69 14572.8 5.559 0.427 6.4 LNU288 14562.9 6.574 0.223 24.4 CONT. — 4.818 — 0.0 LNU288 14564.9 6.230 0.216 17.9 LNU150 24842.9 6.440 0.000 33.7 LNU288 14562.7 5.939 0.495 12.4 LNU150 24843.5 6.075 0.018 26.1 LNU288 14562.12 5.738 0.647 8.6 LNU150 24841.9 5.578 0.117 15.8 LNU50 26025.4 7.278 0.006 37.8 LNU150 24842.5 5.570 0.008 15.6 LNU50 26024.2 7.156 0.012 35.5 LNU179 24631.9 6.537 0.001 35.7 LNU50 26023.5 6.065 0.332 14.8 LNU179 24632.5 6.033 0.024 25.2 LNU50 26023.2 5.464 0.644 3.4 LNU179 24631.6 5.461 0.031 13.4 LNU52 25723.2 7.247 0.018 37.2 LNU179 24632.7 5.320 0.170 10.4 LNU52 25721.4 6.053 0.380 14.6 LNU179 24631.7 5.063 0.520 5.1 LNU52 25721.3 6.011 0.283 13.8 LNU232 26003.3 6.508 0.000 35.1 CONT. — 6.028 — 0.0 LNU232 26003.7 5.627 0.034 16.8 LNU143 25975.3 6.851 0.315 13.6 LNU232 26001.5 5.375 0.159 11.6 LNU143 25975.2 6.827 0.345 13.3 LNU232 26001.2 5.282 0.078 9.6 LNU154 14601.6 8.039 0.364 33.4 LNU232 26003.6 5.071 0.682 5.3 LNU207 24641.1 7.283 0.464 20.8 LNU235 26184.4 6.139 0.000 27.4 LNU207 24642.5 7.096 0.217 17.7 LNU235 26185.3 5.962 0.005 23.7 LNU207 24642.4 6.809 0.368 13.0 LNU235 26182.1 5.822 0.006 20.9 LNU211 24771.1 7.170 0.287 18.9 LNU235 26184.2 5.461 0.120 13.3 LNU52 25723.1 7.431 0.307 23.3 LNU242 25474.1 6.568 0.008 36.3 LNU69 14571.1 7.692 0.211 27.6 LNU242 25473.1 6.326 0.000 31.3 LNU69 14573.3 6.458 0.686 7.1 LNU242 25473.3 6.163 0.003 27.9 LNU69 14572.8 6.374 0.697 5.7 LNU242 25471.1 6.004 0.000 24.6 CONT. — 4.102 — 0.0 LNU242 25472.1 5.035 0.595 4.5 LNU150 24843.5 7.038 0.000 71.6 LNU76 26421.2 6.376 0.020 32.3 LNU150 24842.9 7.011 0.010 70.9 LNU76 26421.1 5.555 0.007 15.3 LNU150 24841.9 6.414 0.003 56.4 LNU76 26422.2 5.466 0.117 13.4 LNU150 24843.9 5.198 0.098 26.7 LNU76 26425.1 5.383 0.280 11.7 LNU179 24631.9 5.977 0.047 45.7 LNU76 26423.1 5.317 0.252 10.4 LNU179 24632.5 5.099 0.209 24.3 LNU95 13985.11 6.468 0.007 34.3 LNU232 26003.7 6.928 0.092 68.9 LNU95 13985.16 5.968 0.001 23.9 LNU232 26003.3 6.034 0.029 47.1 LNU95 13985.19 5.886 0.023 22.2 LNU232 26003.6 4.465 0.691 8.8 LNU95 13985.15 5.821 0.033 20.8 LNU232 26001.5 4.325 0.792 5.4 LNU95 13985.12 5.454 0.255 13.2 LNU235 26185.3 5.570 0.023 35.8 CONT. — 5.596 — 0.0 LNU235 26184.4 5.454 0.110 33.0 LNU150 24842.9 6.495 0.077 16.1 LNU235 26182.1 4.710 0.157 14.8 LNU150 24843.5 5.728 0.782 2.4 LNU235 26184.2 4.681 0.569 14.1 LNU179 24631.7 6.000 0.346 7.2 LNU242 25474.1 7.610 0.042 85.5 LNU179 24631.6 5.967 0.337 6.6 LNU242 25473.1 5.905 0.000 44.0 LNU179 24632.5 5.884 0.329 5.1 LNU242 25471.1 5.858 0.000 42.8 LNU232 26001.5 6.960 0.001 24.4 LNU242 25473.3 4.707 0.315 14.8 LNU232 26003.3 6.334 0.055 13.2 LNU242 25472.1 4.342 0.761 5.8 LNU235 26184.4 6.801 0.001 21.5 LNU76 26421.2 7.302 0.025 78.0 LNU235 26185.2 6.719 0.002 20.1 LNU76 26421.1 5.648 0.015 37.7 LNU235 26184.2 6.703 0.030 19.8 LNU76 26423.1 4.653 0.574 13.4 LNU235 26182.1 6.005 0.414 7.3 LNU76 26422.2 4.641 0.416 13.1 LNU242 25474.1 6.141 0.238 9.7 LNU76 26425.1 4.577 0.624 11.6 LNU288 14563.9 6.445 0.009 15.2 LNU95 13985.11 7.498 0.065 82.8 LNU288 14562.1 6.389 0.118 14.2 LNU95 13985.15 6.783 0.001 65.4 LNU288 14563.6 6.158 0.246 10.1 LNU95 13985.16 5.850 0.119 42.6 LNU288 14562.7 5.913 0.492 5.7 LNU95 13985.19 5.634 0.228 37.3 LNU288 14564.9 5.793 0.539 3.5 LNU95 13985.12 4.641 0.605 13.1 LNU76 26421.2 5.827 0.492 4.1 CONT. — 5.171 — 0.0 LNU95 13985.11 6.313 0.049 12.8 LNU118 14013.6 6.735 0.106 30.3 LNU95 13985.12 6.257 0.025 11.8 LNU118 14012.15 6.697 0.326 29.5 LNU95 13985.16 6.116 0.328 9.3 LNU150 24842.9 7.643 0.119 47.8 LNU95 13985.15 6.092 0.238 8.9 LNU150 24841.9 6.335 0.177 22.5 LNU95 13985.19 5.758 0.625 2.9 LNU150 24843.5 6.217 0.117 20.2 CONT. — 5.840 — 0.0 LNU150 24841.6 5.370 0.709 3.8 LNU101 27632.5 6.847 0.035 17.2 LNU179 24632.7 6.009 0.211 16.2 LNU101 27635.1 6.709 0.082 14.9 LNU179 24631.7 5.926 0.488 14.6 LNU101 27632.7 6.522 0.040 11.7 LNU232 26001.5 8.215 0.001 58.9 LNU101 27632.1 6.490 0.176 11.1 LNU232 26003.3 7.174 0.037 38.7 LNU101 27632.6 6.066 0.662 3.9 LNU235 26184.4 10.268 0.005 98.6 LNU128 26511.4 6.453 0.186 10.5 LNU235 26185.2 7.934 0.016 53.4 LNU128 26515.3 6.427 0.238 10.1 LNU235 26184.2 7.761 0.020 50.1 LNU128 26515.2 6.181 0.362 5.8 LNU235 26182.1 5.904 0.305 14.2 LNU128 26511.5 6.170 0.399 5.7 LNU242 25474.1 7.459 0.024 44.2 LNU192 28313.3 6.947 0.003 19.0 LNU288 14563.9 8.852 0.004 71.2 LNU192 28315.2 6.906 0.021 18.3 LNU288 14562.1 7.472 0.019 44.5 LNU192 28313.2 6.630 0.147 13.5 LNU288 14563.6 6.435 0.217 24.4 LNU206 27621.2 6.699 0.296 14.7 LNU288 14564.9 5.887 0.167 13.9 LNU206 27622.1 5.925 0.681 1.5 LNU288 14562.7 5.436 0.775 5.1 LNU282 27563.3 6.365 0.161 9.0 LNU76 26421.2 5.861 0.250 13.3 LNU69 14573.5 6.062 0.437 3.8 LNU76 26425.1 5.685 0.341 9.9 LNU69 14571.1 5.886 0.769 0.8 LNU76 26422.2 5.561 0.685 7.5 LNU75 27572.1 6.841 0.023 17.2 LNU76 26423.1 5.357 0.778 3.6 LNU75 27572.2 6.360 0.207 8.9 LNU95 13985.15 7.642 0.003 47.8 LNU75 27571.4 6.307 0.312 8.0 LNU95 13985.16 7.507 0.080 45.2 CONT. — 5.421 — 0.0 LNU95 13985.12 6.609 0.092 27.8 LNU101 27635.1 6.330 0.001 16.8 CONT. — 5.155 — 0.0 LNU101 27632.5 6.284 0.042 15.9 LNU101 27632.1 6.954 0.000 34.9 LNU118 14013.9 5.551 0.582 2.4 LNU101 27635.1 6.553 0.015 27.1 LNU128 26515.3 6.567 0.004 21.2 LNU101 27632.5 6.041 0.341 17.2 LNU206 27621.2 7.079 0.000 30.6 LNU101 27632.6 5.659 0.660 9.8 LNU206 27622.4 6.005 0.027 10.8 LNU128 26515.3 8.036 0.036 55.9 LNU206 27622.1 5.675 0.201 4.7 LNU128 26515.2 6.980 0.059 35.4 LNU249 26152.4 6.731 0.047 24.2 LNU128 26511.4 6.416 0.275 24.5 LNU249 26152.2 6.097 0.021 12.5 LNU192 28315.2 7.992 0.006 55.0 LNU249 26151.1 5.809 0.442 7.2 LNU192 28313.2 7.389 0.056 43.3 LNU249 26153.1 5.805 0.330 7.1 LNU192 28313.3 6.309 0.015 22.4 LNU282 27565.2 6.755 0.000 24.6 LNU206 27621.2 7.023 0.099 36.2 LNU282 27562.1 6.371 0.181 17.5 LNU206 27621.1 6.013 0.362 16.6 LNU282 27563.3 6.358 0.001 17.3 LNU211 24771.1 6.969 0.137 35.2 LNU282 27563.1 5.930 0.327 9.4 LNU282 27563.3 6.654 0.242 29.1 LNU282 27565.1 5.878 0.248 8.4 LNU69 14571.1 6.648 0.029 29.0 LNU288 14563.6 6.686 0.019 23.3 LNU69 14573.5 6.575 0.082 27.5 LNU288 14564.8 5.991 0.025 10.5 LNU75 27572.2 7.816 0.048 51.6 LNU288 14562.9 5.894 0.051 8.7 LNU75 27572.3 6.896 0.047 33.8 LNU288 14563.9 5.770 0.351 6.4 LNU75 27572.1 6.642 0.116 28.8 LNU288 14562.7 5.498 0.730 1.4 LNU75 27571.4 5.830 0.472 13.1 LNU75 27571.4 6.877 0.013 26.9 CONT. — 5.119 — 0.0 LNU75 27571.2 6.627 0.007 22.3 LNU101 27632.5 7.394 0.082 44.4 LNU75 27572.2 6.434 0.000 18.7 LNU101 27635.1 5.507 0.659 7.6 LNU75 27572.1 6.343 0.001 17.0 LNU118 14012.15 6.364 0.142 24.3 LNU75 27572.3 6.135 0.197 13.2 LNU118 14013.6 6.134 0.192 19.8 CONT. — 5.851 — 0.0 LNU118 14013.9 5.512 0.470 7.7 LNU11 28203.2 6.770 0.084 15.7 LNU206 27621.2 7.528 0.002 47.1 LNU11 28202.5 6.655 0.030 13.7 LNU249 26153.1 6.400 0.084 25.0 LNU11 28205.2 6.256 0.263 6.9 LNU249 26152.4 5.917 0.429 15.6 LNU11 28204.1 5.953 0.773 1.7 LNU282 27563.1 6.191 0.310 20.9 LNU112 28212.1 7.103 0.025 21.4 LNU282 27565.2 5.531 0.547 8.0 LNU112 28212.4 6.658 0.025 13.8 LNU288 14564.8 7.100 0.026 38.7 LNU14 27823.2 6.785 0.007 16.0 LNU288 14563.6 6.894 0.136 34.7 LNU14 27821.1 6.697 0.015 14.5 LNU288 14562.9 6.758 0.062 32.0 LNU14 27821.3 6.536 0.084 11.7 LNU288 14563.9 6.601 0.128 28.9 LNU183 24864.6 6.449 0.296 10.2 LNU288 14562.7 5.378 0.745 5.1 LNU201 28223.1 6.657 0.018 13.8 LNU75 27572.2 7.467 0.086 45.9 LNU201 28222.3 6.486 0.069 10.9 LNU75 27571.4 7.273 0.099 42.1 LNU201 28223.3 6.296 0.220 7.6 LNU75 27571.2 6.832 0.023 33.5 LNU201 28222.2 6.038 0.526 3.2 LNU75 27572.3 6.252 0.407 22.1 LNU268 26044.2 6.891 0.055 17.8 CONT. — 6.888 — 0.0 LNU268 26041.6 6.017 0.556 2.8 LNU14 27821.3 7.893 0.445 14.6 CONT. — 6.335 — 0.0 LNU14 27823.2 7.231 0.669 5.0 LNU11 28205.2 7.266 0.038 14.7 LNU183 24863.12 7.193 0.724 4.4 LNU11 28203.2 6.971 0.204 10.0 LNU268 26044.2 8.591 0.288 24.7 LNU11 28204.3 6.549 0.598 3.4 CONT. — 6.290 — 0.0 LNU112 28212.4 6.616 0.460 4.4 LNU11 28205.2 9.031 0.002 43.6 LNU112 28212.1 6.561 0.530 3.6 LNU11 28203.2 8.193 0.057 30.3 LNU14 27821.3 7.170 0.048 13.2 LNU11 28205.1 7.731 0.091 22.9 LNU183 24863.1 6.996 0.242 10.4 LNU11 28204.3 7.658 0.100 21.8 LNU183 24864.6 6.598 0.474 4.2 LNU11 28202.5 7.517 0.152 19.5 LNU191 28323.1 6.529 0.614 3.1 LNU11 28204.1 6.773 0.246 7.7 LNU201 28222.2 6.989 0.131 10.3 LNU112 28212.4 7.304 0.058 16.1 LNU268 26043.4 6.545 0.603 3.3 LNU112 28212.1 6.984 0.195 11.0 CONT. — 5.852 — 0.0 LNU14 27821.3 8.988 0.064 42.9 LNU107 14585.5 6.287 0.288 7.4 LNU14 27823.2 7.003 0.606 11.3 LNU116 14492.5 6.136 0.610 4.8 LNU183 24865.1 11.077 0.001 76.1 LNU121 27711.1 6.388 0.223 9.2 LNU183 24863.1 10.729 0.057 70.6 LNU121 27713.4 6.358 0.207 8.7 LNU183 24863.12 8.917 0.023 41.8 LNU126 25343.3 6.722 0.055 14.9 LNU183 24864.6 8.916 0.003 41.8 LNU126 25345.1 6.584 0.135 12.5 LNU191 28323.1 8.175 0.253 30.0 LNU126 25343.1 6.437 0.194 10.0 LNU191 28325.4 6.688 0.356 6.3 LNU126 25343.4 6.144 0.489 5.0 LNU201 28222.2 10.400 0.029 65.4 LNU158 27433.3 7.014 0.109 19.9 LNU201 28223.1 6.822 0.376 8.5 LNU158 27433.2 6.299 0.374 7.6 LNU268 26043.4 8.266 0.057 31.4 LNU158 27432.5 6.176 0.436 5.5 LNU268 26041.6 7.535 0.443 19.8 LNU158 27434.5 6.080 0.686 3.9 LNU268 26041.4 7.476 0.159 18.9 LNU177 24765.2 7.112 0.025 21.5 LNU268 26044.2 6.808 0.370 8.2 LNU177 24762.6 6.607 0.070 12.9 CONT. — 5.249 — 0.0 LNU177 24764.9 6.268 0.392 7.1 LNU107 14585.5 6.577 0.434 25.3 LNU177 24763.6 6.176 0.396 5.5 LNU107 14583.8 6.445 0.293 22.8 LNU182 27521.4 6.800 0.042 16.2 LNU107 14584.9 5.987 0.175 14.1 LNU182 25384.5 6.767 0.101 15.6 LNU116 14492.5 5.750 0.366 9.5 LNU182 25384.1 6.019 0.762 2.8 LNU116 14494.5 5.574 0.589 6.2 LNU2 27842.3 6.959 0.029 18.9 LNU116 14492.9 5.515 0.583 5.1 LNU2 25713.1 6.193 0.445 5.8 LNU121 27713.4 8.247 0.002 57.1 LNU225 25991.5 7.007 0.038 19.7 LNU121 25642.2 7.499 0.133 42.9 LNU225 25991.2 6.717 0.114 14.8 LNU121 27711.1 7.285 0.022 38.8 LNU225 25991.3 6.613 0.172 13.0 LNU121 27713.1 5.912 0.261 12.6 LNU225 25991.1 6.286 0.464 7.4 LNU126 25345.1 7.763 0.024 47.9 LNU239 26284.1 6.856 0.025 17.2 LNU126 25343.3 6.965 0.016 32.7 LNU239 26284.2 6.651 0.068 13.7 LNU126 25343.1 6.521 0.210 24.2 LNU239 26281.1 6.264 0.439 7.0 LNU126 25343.4 5.499 0.674 4.8 LNU239 26283.3 6.028 0.712 3.0 LNU158 27433.3 8.968 0.137 70.8 LNU57 27852.1 6.999 0.020 19.6 LNU158 27433.2 8.046 0.004 53.3 LNU57 27854.3 6.744 0.059 15.2 LNU158 27432.5 6.290 0.360 19.8 LNU83 27684.1 6.527 0.133 11.5 LNU177 24762.6 8.887 0.085 69.3 LNU83 27681.4 6.381 0.260 9.0 LNU177 24765.2 7.192 0.269 37.0 LNU83 27682.1 6.213 0.357 6.2 LNU177 24764.9 5.932 0.179 13.0 LNU83 27685.1 5.973 0.771 2.1 LNU182 25384.5 7.997 0.058 52.3 CONT. — 5.715 — 0.0 LNU182 27521.4 7.490 0.053 42.7 LNU107 14584.9 6.891 0.021 20.6 LNU182 25384.1 6.840 0.039 30.3 LNU107 14583.8 6.667 0.061 16.7 LNU2 27842.3 7.641 0.069 45.6 LNU107 14585.5 6.158 0.237 7.8 LNU2 25713.1 7.344 0.011 39.9 LNU116 14491.5 6.504 0.094 13.8 LNU2 27842.1 6.809 0.436 29.7 LNU116 14494.5 5.784 0.774 1.2 LNU225 25991.5 9.233 0.029 75.9 LNU121 27713.1 7.058 0.001 23.5 LNU225 25991.2 7.038 0.116 34.1 LNU121 27711.1 6.792 0.005 18.9 LNU225 25991.1 6.470 0.244 23.3 LNU121 27713.4 6.571 0.098 15.0 LNU225 25991.3 6.141 0.551 17.0 LNU126 25343.1 7.209 0.000 26.2 LNU239 26284.1 6.751 0.113 28.6 LNU126 25343.4 6.524 0.086 14.2 LNU239 26283.2 5.920 0.548 12.8 LNU126 25345.1 6.324 0.216 10.7 LNU239 26281.1 5.794 0.397 10.4 LNU126 25343.3 6.246 0.108 9.3 LNU57 27852.1 7.854 0.013 49.6 LNU158 27433.3 7.495 0.000 31.2 LNU57 27854.3 6.344 0.102 20.9 LNU158 27432.5 7.179 0.000 25.6 LNU57 27854.5 5.880 0.366 12.0 LNU158 27433.2 7.006 0.002 22.6 LNU83 27681.4 7.249 0.097 38.1 LNU158 27434.1 6.795 0.000 18.9 LNU83 27684.1 5.767 0.589 9.9 LNU158 27434.5 6.698 0.055 17.2 LNU83 27685.1 5.561 0.651 5.9 LNU177 24764.12 7.403 0.006 29.6 CONT. — 4.915 — 0.0 LNU177 24763.6 7.161 0.001 25.3 LNU107 14584.9 10.490 0.008 113.4 LNU177 24765.2 7.070 0.000 23.7 LNU107 14583.8 7.949 0.019 61.7 LNU177 24764.9 5.894 0.552 3.1 LNU107 14585.2 6.870 0.009 39.8 LNU182 25384.2 6.882 0.008 20.4 LNU107 14583.1 5.412 0.458 10.1 LNU182 25384.6 6.781 0.012 18.7 LNU107 14585.5 5.284 0.413 7.5 LNU182 27521.4 6.773 0.017 18.5 LNU116 14493.6 7.433 0.046 51.2 LNU182 25384.1 6.597 0.012 15.5 LNU116 14494.5 7.121 0.098 44.9 LNU182 25384.5 6.430 0.002 12.5 LNU116 14491.5 7.065 0.145 43.8 LNU2 27842.1 7.238 0.000 26.7 LNU116 14492.5 6.075 0.007 23.6 LNU2 25713.1 6.894 0.001 20.6 LNU116 14492.9 5.198 0.791 5.8 LNU2 27842.3 6.701 0.035 17.3 LNU121 27713.4 10.520 0.009 114.1 LNU225 25991.3 7.743 0.000 35.5 LNU121 27713.1 9.336 0.011 90.0 LNU225 25991.5 7.166 0.001 25.4 LNU121 27711.1 7.107 0.029 44.6 LNU225 25991.2 6.660 0.008 16.6 LNU121 25642.2 5.748 0.472 17.0 LNU225 25991.8 6.386 0.139 11.7 LNU126 25343.1 7.086 0.055 44.2 LNU225 25991.1 6.180 0.020 8.1 LNU126 25343.3 5.673 0.262 15.4 LNU239 26284.1 6.838 0.005 19.7 LNU126 25343.4 5.597 0.015 13.9 LNU239 26281.1 6.800 0.002 19.0 LNU126 25345.1 5.517 0.332 12.3 LNU239 26283.3 6.798 0.002 19.0 LNU158 27433.3 10.395 0.000 111.5 LNU239 26284.2 6.544 0.042 14.5 LNU158 27432.5 10.059 0.009 104.7 LNU239 26283.2 6.142 0.233 7.5 LNU158 27433.2 7.322 0.044 49.0 LNU57 27852.1 7.280 0.003 27.4 LNU158 27434.5 7.124 0.031 44.9 LNU57 27854.5 7.061 0.000 23.6 LNU158 27434.1 6.038 0.135 22.9 LNU57 27851.2 7.054 0.000 23.4 LNU177 24764.12 7.964 0.000 62.1 LNU57 27854.3 6.356 0.004 11.2 LNU177 24763.6 6.811 0.057 38.6 LNU83 27685.1 7.354 0.000 28.7 LNU177 24765.2 5.371 0.457 9.3 LNU83 27682.1 7.128 0.034 24.7 LNU182 25384.6 8.604 0.031 75.1 LNU83 27685.2 7.081 0.000 23.9 LNU182 25384.1 7.588 0.003 54.4 LNU83 27681.4 6.754 0.002 18.2 LNU182 25384.2 7.046 0.020 43.4 LNU83 27684.1 6.555 0.118 14.7 LNU182 27521.4 6.026 0.156 22.6 LNU182 25384.5 5.953 0.156 21.1 LNU2 27842.1 8.180 0.000 66.4 LNU2 27842.3 7.899 0.005 60.7 LNU2 25713.1 7.574 0.090 54.1 LNU2 27845.2 5.617 0.386 14.3 LNU225 25991.2 11.048 0.002 124.8 LNU225 25991.3 10.621 0.024 116.1 LNU225 25991.8 7.226 0.094 47.0 LNU225 25991.5 6.962 0.001 41.7 LNU225 25991.1 6.869 0.003 39.8 LNU239 26283.3 7.477 0.057 52.1 LNU239 26281.1 7.013 0.013 42.7 LNU239 26284.2 5.944 0.170 21.0 LNU239 26284.1 5.651 0.207 15.0 LNU239 26283.2 5.605 0.113 14.0 LNU57 27854.5 9.187 0.002 86.9 LNU57 27851.2 9.142 0.003 86.0 LNU57 27852.1 8.944 0.006 82.0 LNU57 27854.3 5.731 0.095 16.6 LNU83 27685.1 8.992 0.003 83.0 LNU83 27685.2 8.420 0.046 71.3 LNU83 27682.1 7.321 0.092 49.0 LNU83 27681.4 6.918 0.004 40.8 LNU83 27684.1 5.685 0.383 15.7 CONT. — 7.469 — LNU17 13991.1 8.395 0.2 12.3 CONT. — 5.518 0.0 LNU129 27501.2 7.071 <0.1 28.2 LNU129 27502.4 6.038 <0.8 9.4 LNU129 27503.4 5.784 <0.8 4.8 LNU129 27504.3 9.078 <0.05 64.5 LNU147 27513.2 7.281 <0.1 32.0 LNU147 27514.2 6.115 <0.8 10.8 LNU153 24851.3 7.253 <0.1 31.4 LNU189 26382.4 6.849 <0.2 24.1 LNU189 26383.1 6.937 <0.2 25.7 LNU189 26385.1 6.744 <0.2 22.2 LNU219 27462.1 8.526 <0.1 54.5 LNU219 27464.2 7.111 <0.1 28.9 LNU256 26212.3 5.987 <0.8 8.5 LNU256 26214.1 8.193 <0.05 48.5 LNU256 26214.2 6.910 <0.2 25.2 LNU257 26254.1 6.804 <0.2 23.3 LNU257 26254.3 9.461 <0.05 71.5 LNU257 26255.3 6.481 <0.5 17.5 LNU261 27403.2 5.664 <0. 9 2.7 LNU33 25552.2 7.217 <0.1 30.8 LNU33 25555.1 5.970 <0.8 8.2 LNU35 27422.1 7.462 <0.1 35.2 LNU35 27424.3 6.419 16.3 LNU35 27424.4 7.739 <0.05 40.2 LNU50 26022.1 7.402 <0.05 34.1 LNU50 26024.1 7.051 <0.1 27.8 LNU50 26025.3 8.616 <0.05 56.1 LNU70 25311.3 5.862 <0.8 6.2 LNU70 25311.4 6.021 <0.8 9.1 LNU70 25313.1 6.324 <0.7 14.6 Table 74. “CONT.”—Control; “Ave”—Average; “% Incr.” = % increment.

TABLE 75 Genes showing improved root performance at standard nitrogen growth conditions (T1 generation) Roots Length [cm] Roots Coverage [cm2] Gene Time p- % Gene Time p- % Name Point Ave. value incr. Name Point Ave. value incr. CONT. Roots 1.840 — 0.0 CONT. Roots 0.925 — 0.0 Length Coverage TP2 TP2 LNU107 Roots 1.922 0.619 4.4 LNU118 Roots 0.951 0.651 2.9 Length Coverage TP2 TP2 LNU118 Roots 1.856 0.869 0.9 LNU121 Roots 1.581 0.007 70.9 Length Coverage TP2 TP2 LNU121 Roots 2.431 0.015 32.1 LNU150 Roots 0.939 0.839 1.6 Length Coverage TP2 TP2 LNU154 Roots 2.237 0.176 21.5 LNU154 Roots 1.227 0.250 32.7 Length Coverage TP2 TP2 LNU210 Roots 2.124 0.122 15.4 LNU210 Roots 1.180 0.032 27.7 Length Coverage TP2 TP2 LNU68 Roots 1.915 0.646 4.1 LNU68 Roots 0.931 0.961 0.6 Length Coverage TP2 TP2 CONT. Roots_ 3.468 — 0.0 CONT. Roots 2.488 — 0.0 Length_TP3 Coverage TP3 LNU121 Roots_ 4.286 0.007 23.6 LNU121 Roots 4.048 0.000 62.7 Length_TP3 Coverage TP3 LNU154 Roots_ 3.653 0.613 5.4 LNU154 Roots 2.785 0.583 12.0 Length_TP3 Coverage TP3 LNU210 Roots_ 3.707 0.366 6.9 LNU210 Roots 2.770 0.188 11.3 Length_TP3 Coverage TP3 CONT. Roots 1.572 — 0.0 CONT. Roots 1.015 — 0.0 Length Coverage TP2 TP2 LNU127 Roots 1.797 0.327 14.3 LNU265 Roots 1.029 0.935 1.3 Length Coverage TP2 TP2 LNU188 Roots 1.769 0.191 12.5 LNU275 Roots 2.413 0.003 137.6 Length Coverage TP2 TP2 LNU2 Roots 1.673 0.574 6.4 LNU57 Roots 1.571 0.008 54.7 Length Coverage TP2 TP2 LNU239 Roots 1.895 0.214 20.5 LNU58 Roots 1.301 0.143 28.1 Length Coverage TP2 TP2 LNU258 Roots 1.648 0.689 4.8 LNU83 Roots 1.659 0.013 63.3 Length Coverage TP2 TP2 LNU265 Roots 1.947 0.030 23.8 CONT. Roots 2.621 — 0.0 Length Coverage TP2 TP3 LNU275 Roots 2.607 0.002 65.8 LNU275 Roots 7.009 0.005 167.5 Length Coverage TP2 TP3 LNU32 Roots 1.886 0.107 20.0 LNU57 Roots 4.363 0.004 66.5 Length Coverage TP2 TP3 LNU57 Roots 2.332 0.000 48.3 LNU58 Roots 3.190 0.066 21.7 Length Coverage TP2 TP3 LNU58 Roots 2.138 0.001 36.0 LNU83 Roots 4.487 0.007 71.2 Length Coverage TP2 TP3 LNU64 Roots 1.642 0.633 4.4 CONT. Roots 0.613 — 0.0 Length Coverage TP2 TP2 LNU83 Roots 2.568 0.001 63.3 LNU176 Roots 0.663 0.738 8.2 Length Coverage TP2 TP2 CONT. Roots_ 3.387 — 0.0 LNU214 Roots 0.845 0.016 38.0 Length_TP3 Coverage TP2 LNU239 Roots_ 3.480 0.842 2.7 LNU223 Roots 0.741 0.189 20.9 Length_TP3 Coverage TP2 LNU265 Roots_ 3.489 0.675 3.0 LNU233 Roots 0.764 0.159 24.7 Length_TP3 Coverage TP2 LNU275 Roots_ 4.574 0.017 35.0 LNU245 Roots 0.794 0.027 29.6 Length_TP3 Coverage TP2 LNU57 Roots_ 4.598 0.002 35.7 LNU247 Roots 0.673 0.653 9.9 Length_TP3 Coverage TP2 LNU58 Roots_ 3.745 0.059 10.5 LNU251 Roots 0.645 0.748 5.2 Length_TP3 Coverage TP2 LNU83 Roots_ 4.733 0.003 39.7 LNU284 Roots 0.710 0.330 15.8 Length_TP3 Coverage TP2 CONT. Roots 1.563 — 0.0 LNU289 Roots 0.880 0.014 43.6 Length Coverage TP2 TP2 LNU176 Roots 1.695 0.430 8.4 LNU70 Roots 0.902 0.041 47.1 Length Coverage TP2 TP2 LNU214 Roots 2.127 0.006 36.1 LNU85 Roots 0.852 0.012 39.0 Length Coverage TP2 TP2 LNU223 Roots 1.907 0.005 22.0 LNU86 Roots 0.665 0.618 8.5 Length Coverage TP2 TP2 LNU233 Roots 1.932 0.003 23.6 CONT. Roots 1.504 — 0.0 Length Coverage TP2 TP3 LNU245 Roots 2.021 0.001 29.3 LNU176 Roots 2.038 0.118 35.5 Length Coverage TP2 TP3 LNU247 Roots 1.690 0.621 8.1 LNU214 Roots 1.816 0.190 20.7 Length Coverage TP2 TP3 LNU215 Roots 1.944 0.251 24.4 LNU223 Roots 1.925 0.066 27.9 Length Coverage TP2 TP3 LNU284 Roots 1.925 0.198 23.2 LNU233 Roots 1.884 0.253 25.2 Length Coverage TP2 TP3 LNU289 Roots 2.082 0.003 33.2 LNU245 Roots 1.644 0.332 9.3 Length Coverage TP2 TP3 LNU70 Roots 1.921 0.157 22.9 LNU247 Roots 1.527 0.933 1.5 Length Coverage TP2 TP3 LNU85 Roots 2.118 0.007 35.5 LNU284 Roots 1.802 0.345 19.8 Length Coverage TP2 TP3 LNU86 Roots 1.690 0.435 8.1 LNU289 Roots 1.991 0.011 32.4 Length Coverage TP2 TP3 CONT. Roots_ 2.862 — 0.0 LNU70 Roots 2.020 0.140 34.2 Length_TP3 Coverage TP3 LNU176 Roots_ 3.292 0.150 15.0 LNU85 Roots 2.097 0.066 39.4 Length_TP3 Coverage TP3 LNU214 Roots_ 3.448 0.062 20.5 LNU86 Roots 1.521 0.955 1.1 Length_TP3 Coverage TP3 LNU223 Roots_ 3.310 0.050 15.6 CONT. Roots 1.338 — 0.0 Length_TP3 Coverage TP2 LNU233 Roots_ 3.361 0.073 17.5 LNU105 Roots 1.395 0.693 4.3 Length_TP3 Coverage TP2 LNU245 Roots_ 3.407 0.043 19.0 LNU115 Roots 1.405 0.617 5.0 Length_TP3 Coverage TP2 LNU247 Roots_ 2.993 0.659 4.6 LNU134 Roots 1.689 0.236 26.2 Length_TP3 Coverage TP2 LNU251 Roots_ 2.986 0.779 4.3 LNU190 Roots 1.556 0.392 16.3 Length_TP3 Coverage TP2 LNU284 Roots_ 3.321 0.267 16.0 LNU198 Roots 1.410 0.715 5.4 Length_TP3 Coverage TP2 LNU289 Roots_ 3.375 0.016 17.9 LNU200 Roots 1.753 0.054 31.0 Length_TP3 Coverage TP2 LNU70 Roots_ 3.398 0.192 18.7 CONT. Roots 3.172 — 0.0 Length_TP3 Coverage TP3 LNU85 Roots_ 3.726 0.032 30.2 LNU105 Roots 3.383 0.707 6.7 Length_TP3 Coverage TP3 CONT. Roots 2.410 — 0.0 LNU115 Roots 3.577 0.321 12.8 Length Coverage TP2 TP3 LNU105 Roots 2.686 0.077 11.5 LNU134 Roots 3.704 0.399 16.8 Length Coverage TP2 TP3 LNU115 Roots 2.523 0.420 4.7 LNU190 Roots 3.202 0.958 1.0 Length Coverage TP2 TP3 LNU123 Roots 2.532 0.386 5.1 LNU198 Roots 3.239 0.885 2.1 Length Coverage TP2 TP3 LNU134 Roots 2.759 0.093 14.4 LNU200 Roots 3.387 0.625 6.8 Length Coverage TP2 TP3 LNU190 Roots 2.613 0.533 8.4 CONT. Roots 1.312 — 0.0 Length Coverage TP2 TP2 LNU198 Roots 2.559 0.606 6.2 LNU51 Roots 1.395 0.554 6.4 Length Coverage TP2 TP2 LNU200 Roots 2.803 0.129 16.3 LNU59 Roots 1.312 0.999 0.0 Length Coverage TP2 TP2 CONT. Roots_ 3.919 — 0.0 CONT. Roots 3.140 — 0.0 Length_TP3 Coverage TP3 LNU105 Roots_ 4.351 0.235 11.0 LNU51 Roots 3.256 0.671 3.7 Length_TP3 Coverage TP3 LNU115 Roots_ 4.242 0.218 8.3 LNU59 Roots 3.253 0.612 3.6 Length_TP3 Coverage TP3 LNU134 Roots_ 4.380 0.178 11.8 Length_TP3 LNU190 Roots_ 3.931 0.978 0.3 Length_TP3 LNU198 Roots_ 4.030 0.799 2.9 Length_TP3 LNU200 Roots_ 4.038 0.734 3.0 Length_TP3 CONT. Roots 2.210 — 0.0 Length TP2 LNU225 Roots 2.248 0.809 1.7 Length TP2 LNU243 Roots 2.283 0.627 3.3 Length TP2 LNU244 Roots 2.266 0.846 2.6 Length TP2 LNU51 Roots 2.712 0.022 22.7 Length TP2 LNU59 Roots 2.522 0.315 14.1 Length TP2 LNU60 Roots 2.420 0.377 9.5 Length TP2 CONT. Roots_ 4.117 — 0.0 Length_TP3 LNU225 Roots_ 4.183 0.834 1.6 Length_TP3 LNU244 Roots_ 4.133 0.973 0.4 Length_TP3 LNU51 Roots_ 4.561 0.105 10.8 Length_TP3 LNU59 Roots_ 4.405 0.210 7.0 Length_TP3 LNU60 Roots_ 4.125 0.984 0.2 Length_TP3 Table 75. “CONT.”—Control; “Ave.”—Average; “% Incr.”—% increment.

The genes listed in Tables 76 and 77 improved plant growth rate (leaf area, root length and root coverage growth rate) when grown at standard nitrogen concentration levels. These produced plants that grew faster than control plants when grown under standard nitrogen growth conditions. Faster growth was observed when growth rate of leaf area and root length and coverage was measured. The genes were cloned under the regulation of a constitutive promoter (At6669) or root preferred promoter (RootP). Evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one tissue culture assay resulting in positive results as well. Event with p-value <0.1 was considered statistically significant

TABLE 76 Genes showing improved growth rate at standard nitrogen growth conditions (T2 generation) RGR Of Leaf Area RGR of Roots Coverage RGR of Roots Length Gene Event p- % Gene Event p- % Gene Event p- % name # Ave. value incr. name # Ave. value incr. name # Ave. value incr. CONT. — 0.05 — 0 CONT. — 0.47 — 0 CONT. — 0.42 — 0 LNU100 14474.3 0.09 0.02 72 LNU100 14474.3 0.67 0.03 42 LNU100 14471.4 0.49 0.34 16 LNU100 14474.4 0.06 0.20 29 LNU100 14474.4 0.66 0.08 42 LNU100 14474.4 0.48 0.29 13 LNU100 14471.4 0.05 0.50 10 LNU100 14471.4 0.60 0.09 29 LNU100 14474.3 0.47 0.19 11 LNU104 25033.3 0.07 0.03 51 LNU104 25033.3 0.60 0.09 28 LNU100 14473.1 0.46 0.26 10 LNU213 24654.4 0.09 0.01 81 LNU213 24654.4 0.73 0.01 56 LNU100 14473.3 0.44 0.72 4 LNU213 24653.2 0.09 0.00 79 LNU213 24653.2 0.66 0.01 41 LNU104 25033.3 0.49 0.07 17 LNU213 24651.1 0.06 0.04 31 LNU213 24651.1 0.58 0.11 24 LNU213 24654.4 0.49 0.14 17 LNU218 24783.2 0.11 0.00 121 LNU218 24783.2 0.93 0.00 98 LNU213 24653.2 0.48 0.14 15 LNU218 24781.7 0.06 0.07 31 LNU218 24781.2 0.57 0.16 22 LNU213 24651.1 0.45 0.61 6 LNU4 25134.1 0.07 0.01 41 LNU218 24781.7 0.55 0.20 18 LNU218 24783.2 0.65 0.00 54 LNU4 25134.2 0.05 0.51 10 LNU4 25134.1 0.55 0.18 19 LNU218 24781.2 0.45 0.35 8 LNU48 24803.2 0.08 0.01 53 LNU48 24802.2 0.58 0.15 25 LNU218 24781.4 0.45 0.46 8 LNU48 24802.2 0.06 0.07 28 LNU48 24804.4 0.54 0.43 15 LNU4 25134.1 0.48 0.28 14 LNU48 24804.4 0.06 0.21 21 LNU48 24803.8 0.53 0.38 12 LNU4 25131.1 0.44 0.67 4 LNU8 25063.1 0.08 0.01 57 LNU8 25063.1 0.87 0.00 87 LNU48 24802.2 0.44 0.65 5 LNU8 25062.2 0.07 0.04 45 LNU8 25062.2 0.58 0.08 24 LNU48 24804.4 0.44 0.64 5 LNU8 25063.6 0.06 0.08 29 LNU94 24833.1 0.49 0.73 5 LNU8 25063.1 0.57 0.00 36 LNU94 24833.3 0.06 0.17 20 CONT. — 0.64 — 0 LNU8 25062.2 0.49 0.10 17 LNU94 24834.1 0.05 0.78 5 LNU1 24682.2 0.87 0.04 36 LNU94 24834.1 0.43 0.80 3 CONT. — 0.08 — 0 LNU1 24684.1 0.77 0.13 20 CONT. — 0.56 — 0 LNU1 24681.3 0.09 0.30 19 LNU1 24682.1 0.77 0.08 20 LNU 24682.2 0.59 0.70 4 LNU 24682.2 0.09 0.37 15 LNU1 24681.1 0.71 0.36 11 LNU178 14614.5 0.59 0.51 5 LNU133 24744.3 0.13 0.00 70 LNU133 24744.3 1.13 0.00 77 LNU215 24661.4 0.58 0.79 3 LNU133 24741.1 0.13 0.01 69 LNU133 24741.1 1.06 0.02 65 CONT. — 0.53 — 0 LNU175 24732.1 0.11 0.03 42 LNU133 24741.2 0.74 0.16 16 LNU120 25463.7 0.71 0.00 34 LNU175 24734.4 0.11 0.03 42 LNU175 24732.1 1.10 0.00 71 LNU120 25463.6 0.58 0.18 11 LNU175 24732.4 0.09 0.47 12 LNU175 24732.4 1.05 0.00 64 LNU120 25463.3 0.58 0.23 10 LNU175 24731.2 0.08 0.66 7 LNU175 24734.4 0.98 0.00 53 LNU120 25464.1 0.55 0.68 4 LNU178 14614.5 0.10 0.09 29 LNU175 24731.2 0.70 0.52 10 LNU124 14502.7 0.59 0.17 12 LNU178 14611.5 0.09 0.10 19 LNU178 14614.5 1.05 0.00 63 LNU124 14501.1 0.57 0.33 8 LNU178 14611.1 0.08 0.77 3 LNU178 14611.5 0.89 0.05 40 LNU124 14502.1 0.55 0.53 5 LNU215 24664.3 0.13 0.00 69 LNU178 14612.1 0.74 0.31 15 LNU124 14501.7 0.55 0.62 4 LNU215 24661.4 0.09 0.32 12 LNU178 14611.4 0.67 0.73 4 LNU132 14102.9 0.58 0.19 11 LNU24 24973.1 0.10 0.03 36 LNU215 24664.3 1.12 0.00 74 LNU132 14102.7 0.54 0.78 3 LNU24 24971.4 0.09 0.08 21 LNU215 24661.4 0.88 0.00 38 LNU140 14111.6 0.57 0.22 9 LNU24 24971.2 0.08 0.39 10 LNU215 24663.4 0.70 0.47 10 LNU140 14114.8 0.57 0.36 8 LNU6 24992.3 0.14 0.02 85 LNU215 24664.2 0.67 0.73 4 LNU140 14112.7 0.55 0.62 4 LNU6 24993.3 0.09 0.46 15 LNU24 24971.4 0.98 0.02 53 LNU180 24723.3 0.60 0.10 14 LNU82 24823.1 0.11 0.21 37 LNU24 24973.1 0.90 0.07 40 LNU180 24724.3 0.59 0.22 11 LNU9 25001.3 0.11 0.00 45 LNU6 24992.3 1.04 0.03 63 LNU196 25533.3 0.55 0.65 4 CONT. — 0.04 — 0 LNU6 24993.3 0.78 0.38 22 LNU20 24933.2 0.59 0.20 11 LNU120 25463.7 0.08 0.00 74 LNU82 24823.1 0.84 0.10 32 LNU20 24933.4 0.55 0.52 5 LNU120 25463.3 0.06 0.00 39 LNU82 24824.3 0.68 0.59 7 LNU36 25562.3 0.62 0.04 17 LNU120 25463.6 0.06 0.01 34 LNU9 25001.3 0.96 0.00 49 LNU71 25853.4 0.54 0.78 2 LNU124 14501.7 0.07 0.00 69 LNU9 25001.1 0.83 0.03 29 CONT. — 0.51 — 0 LNU124 14501.1 0.06 0.01 35 LNU9 25001.2 0.71 0.37 11 LNU1 24682.1 0.56 0.52 10 LNU124 14502.7 0.05 0.10 25 CONT. — 0.54 — 0 LNU1 24683.2 0.56 0.54 10 LNU124 14502.1 0.05 0.58 6 LNU120 25463.7 0.96 0.00 77 LNU1 24681.1 0.55 0.64 7 LNU132 14102.7 0.06 0.00 40 LNU120 25463.6 0.72 0.02 33 LNU1 24681.3 0.54 0.70 6 LNU132 14102.9 0.06 0.02 29 LNU120 25463.3 0.62 0.22 14 LNU110 24953.2 0.63 0.12 24 LNU132 14101.9 0.05 0.62 6 LNU124 14502.7 0.72 0.02 32 LNU110 24954.3 0.58 0.34 13 LNU140 14112.7 0.07 0.01 51 LNU124 14501.7 0.68 0.09 24 LNU175 2473.34 0.61 0.19 19 LNU140 14111.6 0.06 0.05 27 LNU124 14502.1 0.62 0.20 15 LNU175 24732.1 0.60 0.20 18 LNU140 14114.8 0.05 0.38 10 LNU124 14501.1 0.60 0.40 11 LNU175 24734.4 0.58 0.36 13 LNU180 24724.3 0.08 0.00 87 LNU132 14102.7 0.66 0.11 22 LNU175 24733.1 0.58 0.40 13 LNU180 24723.3 0.06 0.05 45 LNU132 14102.9 0.63 0.21 16 LNU175 24732.2 0.54 0.65 6 LNU180 24721.4 0.05 0.18 20 LNU140 14111.6 0.70 0.04 29 LNU19 25151.11 0.54 0.71 5 LNU196 25534.1 0.07 0.00 66 LNU140 14112.7 0.67 0.10 23 LNU215 24664.2 0.65 0.07 27 LNU196 25533.1 0.05 0.06 24 LNU140 14114.8 0.65 0.09 21 LNU215 24663.4 0.59 0.31 15 LNU196 25533.3 0.05 0.22 23 LNU180 24724.3 0.80 0.00 47 LNU215 24663.3 0.59 0.29 15 LNU20 24933.2 0.07 0.01 52 LNU180 24723.3 0.69 0.06 27 LNU215 24661.4 0.57 0.39 12 LNU20 24932.4 0.05 0.73 4 LNU180 24721.4 0.59 0.42 10 LNU27 24873.1 0.60 0.23 18 LNU36 25562.3 0.07 0.00 50 LNU180 24724.1 0.58 0.58 6 LNU27 24871.4 0.57 0.40 12 LNU36 25562.4 0.05 0.10 23 LNU196 25534.1 0.70 0.06 29 LNU27 24873.4 0.57 0.48 11 LNU36 25561.2 0.05 0.48 9 LNU196 25533.3 0.60 0.46 11 LNU44 24922.3 0.62 0.16 21 LNU71 25853.4 0.08 0.00 72 LNU196 25533.1 0.59 0.51 9 LNU44 24924.2 0.61 0.25 18 LNU71 25852.4 0.05 0.07 23 LNU20 24933.2 0.77 0.01 42 LNU44 24923.3 0.58 0.34 14 CONT. — 0.06 — 0 LNU20 24932.4 0.62 0.25 15 LNU44 24923.1 0.57 0.43 11 LNU1 24681.3 0.07 0.01 24 LNU20 24933.4 0.57 0.66 5 LNU54 24901.2 0.69 0.03 34 LNU110 24952.3 0.06 0.42 8 LNU36 25562.3 0.90 0.00 66 LNU54 24902.4 0.67 0.06 31 LNU110 24953.3 0.06 0.76 4 LNU36 25562.4 0.65 0.15 20 LNU54 24902.7 0.59 0.27 15 LNU175 24733.4 0.09 0.00 53 LNU71 25853.4 0.80 0.00 48 LNU54 24903.3 0.57 0.50 11 LNU175 24732.2 0.08 0.15 37 CONT. — 0.60 — 0 LNU54 24903.5 0.54 0.74 5 LNU19 25151.1 0.08 0.01 31 LNU1 24681.3 0.74 0.12 23 LNU79 24881.1 0.66 0.05 29 LNU215 24663.4 0.09 0.01 48 LNU1 24683.2 0.63 0.80 5 LNU79 24882.2 0.62 0.14 22 LNU27 24873.1 0.09 0.00 53 LNU110 24952.3 0.67 0.49 11 LNU79 24884.4 0.54 0.67 6 LNU44 24924.3 0.09 0.01 44 LNU110 24953.3 0.62 0.80 4 CONT. — 0.51 — 0 LNU54 24903.5 0.08 0.07 32 LNU175 24733.4 1.10 0.00 83 LNU109 24892.6 0.58 0.03 14 LNU54 24902.4 0.07 0.43 9 LNU175 24732.2 0.80 0.07 32 LNU109 24892.5 0.56 0.14 10 LNU79 24884.4 0.09 0.00 51 LNU175 24734.4 0.69 0.34 14 LNU109 24891.2 0.54 0.37 6 LNU79 24881.1 0.08 0.00 41 LNU175 24732.1 0.68 0.40 13 LNU109 24892.8 0.53 0.59 4 LNU79 24884.3 0.07 0.09 22 LNU19 25151.1 0.69 0.29 15 LNU109 24891.5 0.52 0.68 2 CONT. — 0.07 — 0 LNU19 25153.3 0.63 0.73 5 LNU110 24952.3 0.59 0.10 15 LNU109 24891.2 0.11 0.00 71 LNU215 24663.4 0.92 0.01 53 LNU110 24952.1 0.58 0.18 13 LNU109 24892.6 0.10 0.00 50 LNU215 24664.2 0.83 0.05 39 LNU110 24953.2 0.56 0.49 9 LNU109 24892.5 0.09 0.12 33 LNU215 24663.3 0.68 0.39 13 LNU110 24954.1 0.56 0.37 9 LNU109 24891.5 0.08 0.08 23 LNU215 24663.1 0.65 0.71 9 LNU110 24954.3 0.53 0.57 4 LNU110 24952.1 0.13 0.00 88 LNU27 24873.1 0.96 0.00 60 LNU133 24744.3 0.61 0.04 19 LNU110 24954.1 0.11 0.00 67 LNU27 24873.4 0.72 0.27 19 LNU133 24741.2 0.56 0.16 10 LNU110 24952.3 0.10 0.01 52 LNU27 24871.4 0.70 0.27 17 LNU133 24741.1 0.56 0.20 10 LNU110 24953.2 0.10 0.00 51 LNU44 24924.2 0.78 0.05 30 LNU133 24742.2 0.54 0.34 5 LNU110 24954.3 0.09 0.01 36 LNU44 24924.3 0.76 0.14 26 LNU19 25151.11 0.54 0.38 6 LNU133 24741.2 0.13 0.00 93 LNU44 24923.3 0.74 0.21 22 LNU19 25151.1 0.53 0.62 3 LNU133 24741.1 0.13 0.00 89 LNU44 24922.3 0.65 0.61 8 LNU27 24873.1 0.62 0.05 21 LNU133 24744.3 0.12 0.00 81 LNU44 24923.1 0.63 0.78 4 LNU27 24871.4 0.61 0.00 19 LNU133 24742.2 0.10 0.00 54 LNU54 24902.4 0.91 0.02 52 LNU27 24873.4 0.54 0.39 5 LNU133 24744.2 0.10 0.00 47 LNU54 24901.2 0.85 0.06 41 LNU44 24924.3 0.54 0.29 6 LNU19 25151.1 0.13 0.00 89 LNU54 24903.5 0.80 0.06 34 LNU44 24923.3 0.54 0.64 5 LNU19 25153.3 0.09 0.06 39 LNU54 24903.3 0.76 0.15 26 LNU44 24922.3 0.53 0.56 4 LNU19 25151.11 0.08 0.20 14 LNU79 24881.1 1.13 0.00 88 LNU54 24901.2 0.60 0.01 18 LNU27 24873.4 0.13 0.00 94 LNU79 24884.4 0.82 0.03 36 LNU54 24902.4 0.56 0.26 9 LNU27 24871.4 0.09 0.02 35 LNU79 24884.3 0.70 0.28 17 LNU54 24903.5 0.56 0.16 8 LNU27 24873.1 0.08 0.12 16 LNU79 24882.2 0.69 0.45 14 LNU54 24903.3 0.53 0.67 3 LNU44 24922.3 0.11 0.00 69 CONT. — 0.70 — 0 LNU6 24992.3 0.60 0.08 17 LNU44 24924.3 0.09 0.01 38 LNU109 24892.6 1.14 0.00 64 LNU6 24994.2 0.60 0.02 17 LNU44 24923.1 0.08 0.03 24 LNU109 24892.5 0.98 0.05 41 LNU6 24994.5 0.58 0.11 12 LNU44 24924.2 0.07 0.75 4 LNU109 24891.2 0.88 0.06 26 LNU79 24882.2 0.57 0.18 10 LNU54 24903.5 0.13 0.00 100 LNU109 24891.5 0.86 0.09 23 LNU79 24881.1 0.56 0.27 9 LNU54 24902.4 0.10 0.02 54 LNU109 24892.8 0.72 0.78 3 LNU79 24883.2 0.56 0.18 8 LNU54 24901.2 0.09 0.04 36 LNU110 24952.1 1.18 0.00 69 LNU79 24884.4 0.55 0.31 7 LNU6 24994.5 0.12 0.00 85 LNU110 24954.1 1.06 0.00 51 CONT. — 0.74 — 0 LNU6 24992.3 0.12 0.00 84 LNU110 24953.2 1.04 0.03 49 LNU109 24892.8 0.59 0.00 25 LNU6 24994.2 0.09 0.06 30 LNU110 24952.3 0.99 0.02 42 LNU109 24892.6 0.51 0.44 8 LNU6 24994.1 0.09 0.13 28 LNU110 24954.3 0.98 0.01 40 LNU109 24891.5 0.51 0.35 8 LNU79 24882.2 0.12 0.00 76 LNU133 24744.3 1.15 0.00 65 LNU143 25972.1 0.56 0.11 18 LNU79 24881.1 0.11 0.00 68 LNU133 24741.2 1.09 0.00 56 LNU143 25975.3 0.53 0.04 12 LNU79 24884.4 0.10 0.01 55 LNU133 24741.1 1.05 0.00 51 LNU143 25971.5 0.52 0.18 11 LNU79 24883.2 0.10 0.01 52 LNU133 24742.2 0.92 0.04 33 LNU143 25975.2 0.50 0.60 5 LNU79 24884.3 0.10 0.01 49 LNU133 24744.2 0.87 0.08 25 LNU154 14601.6 0.55 0.04 17 CONT. — 0.05 — 0 LNU19 25151.1 1.04 0.00 50 LNU154 14604.6 0.50 0.48 6 LNU109 24892.8 0.11 0.00 100 LNU19 25151.11 0.88 0.04 27 LNU154 14604.5 0.49 0.68 3 LNU109 24891.5 0.09 0.02 61 LNU19 25153.3 0.88 0.13 27 LNU196 25532.2 0.53 0.19 13 LNU109 24891.2 0.08 0.04 47 LNU27 24873.4 1.01 0.02 45 LNU196 25534.1 0.52 0.29 10 LNU109 24892.6 0.06 0.63 10 LNU27 24873.1 0.92 0.03 32 LNU207 24641.1 0.55 0.04 17 LNU143 25975.2 0.07 0.01 35 LNU27 24871.4 0.92 0.05 32 LNU207 24644.18 0.52 0.30 11 LNU143 25972.1 0.07 0.14 33 LNU44 24922.3 1.19 0.00 71 LNU207 24642.5 0.52 0.30 10 LNU143 25975.3 0.06 0.22 14 LNU44 24923.3 0.97 0.05 39 LNU207 24642.4 0.51 0.40 9 LNU154 14604.7 0.09 0.00 55 LNU44 24924.3 0.76 0.50 9 LNU207 24644.13 0.51 0.27 8 LNU154 14601.6 0.07 0.14 27 LNU44 24923.1 0.74 0.63 6 LNU288 14562.7 0.55 0.04 17 LNU154 14604.6 0.07 0.15 27 LNU54 24903.5 1.09 0.00 56 LNU288 14562.9 0.51 0.43 9 LNU154 14602.8 0.07 0.18 19 LNU54 24902.4 0.88 0.20 26 LNU288 14564.9 0.50 0.48 5 LNU196 25532.2 0.11 0.01 98 LNU54 24901.2 0.84 0.25 21 LNU288 14562.1 0.49 0.71 3 LNU196 25534.1 0.09 0.00 59 LNU54 24903.3 0.76 0.41 10 LNU50 26025.4 0.53 0.09 13 LNU196 25531.2 0.06 0.40 16 LNU6 24992.3 1.13 0.00 62 LNU50 26024.2 0.53 0.08 12 LNU207 24642.5 0.10 0.00 82 LNU6 24994.5 1.11 0.02 59 LNU50 26023.2 0.52 0.18 11 LNU207 24642.4 0.07 0.05 32 LNU6 24994.2 1.03 0.01 47 LNU52 25723.2 0.50 0.56 6 LNU207 24644.18 0.07 0.15 22 LNU6 24994.1 0.77 0.54 10 LNU52 25721.3 0.50 0.63 6 LNU207 24644.13 0.06 0.39 14 LNU79 24884.4 1.05 0.02 51 CONT. — 0.44 — 0 LNU207 24641.1 0.06 0.42 10 LNU79 24881.1 1.02 0.02 46 LNU143 25971.2 0.56 0.03 28 LNU288 14564.9 0.08 0.01 46 LNU79 24883.2 0.98 0.01 41 LNU143 25975.3 0.54 0.05 23 LNU288 14562.12 0.07 0.11 31 LNU79 24884.3 0.98 0.03 40 LNU143 25975.2 0.52 0.07 19 LNU288 14562.7 0.07 0.18 21 LNU79 24882.2 0.96 0.01 38 LNU143 25971.5 0.51 0.22 16 LNU288 14562.1 0.07 0.14 20 CONT. — 0.59 — 0 LNU143 25972.1 0.47 0.52 8 LNU288 14562.9 0.07 0.15 20 LNU109 24892.8 0.94 0.00 59 LNU154 14601.6 0.59 0.00 36 LNU50 26024.2 0.08 0.01 50 LNU109 24891.5 0.87 0.00 47 LNU207 24641.1 0.58 0.06 33 LNU50 26025.4 0.07 0.04 34 LNU143 25975.2 0.75 0.05 27 LNU207 24642.5 0.53 0.08 22 LNU50 26023.5 0.06 0.80 4 LNU143 25972.1 0.67 0.43 13 LNU207 24642.4 0.49 0.26 13 LNU52 25721.3 0.09 0.01 59 LNU143 25975.3 0.66 0.39 12 LNU207 24644.15 0.49 0.42 12 LNU52 25723.2 0.08 0.00 54 LNU154 14604.7 0.77 0.03 30 LNU211 24771.1 0.58 0.01 33 LNU52 25721.4 0.07 0.18 29 LNU154 14601.6 0.73 0.15 23 LNU211 24774.4 0.47 0.49 8 CONT. — 0.07 — 0 LNU196 25532.2 0.86 0.15 45 LNU211 24771.3 0.47 0.48 8 LNU154 14601.6 0.08 0.38 25 LNU196 25534.1 0.78 0.01 33 LNU211 24773.7 0.46 0.77 4 LNU207 24642.5 0.10 0.00 47 LNU207 24642.5 0.77 0.16 31 LNU52 25723.1 0.57 0.01 30 LNU207 24642.4 0.08 0.27 17 LNU207 24642.4 0.75 0.12 27 LNU52 25721.1 0.47 0.44 8 LNU52 25721.4 0.09 0.02 40 LNU207 24644.18 0.72 0.29 22 LNU69 14571.1 0.57 0.04 30 LNU52 25721.1 0.08 0.11 24 LNU207 24644.13 0.67 0.27 14 LNU69 14573.3 0.51 0.12 17 LNU52 25723.1 0.08 0.31 15 LNU207 24641.1 0.65 0.59 10 LNU69 14572.8 0.51 0.23 16 LNU69 14571.1 0.08 0.11 25 LNU288 14562.9 0.78 0.13 31 CONT. — 0.39 — 0 LNU69 14572.8 0.07 0.68 7 LNU288 14564.9 0.70 0.26 18 LNU150 24842.9 0.59 0.01 51 CONT. — 0.06 — 0 LNU288 14562.7 0.69 0.37 17 LNU150 24841.9 0.47 0.25 21 LNU150 24843.5 0.09 0.15 32 LNU288 14562.12 0.63 0.69 7 LNU150 24843.9 0.46 0.33 19 LNU150 24841.9 0.09 0.15 32 LNU50 26025.4 0.84 0.00 43 LNU150 24842.5 0.46 0.32 18 LNU150 24842.9 0.08 0.22 26 LNU50 26024.2 0.83 0.02 41 LNU150 24843.5 0.45 0.40 16 LNU150 24843.9 0.07 0.49 15 LNU50 26023.5 0.70 0.26 18 LNU179 24631.9 0.57 0.02 45 LNU232 26003.7 0.08 0.20 28 LNU50 26023.2 0.62 0.69 5 LNU179 24632.7 0.48 0.20 24 LNU235 26184.4 0.07 0.73 7 LNU52 25723.2 0.82 0.01 39 LNU179 24631.6 0.47 0.24 21 LNU242 25474.1 0.09 0.04 45 LNU52 25721.4 0.70 0.29 19 LNU179 24631.7 0.45 0.37 17 LNU242 25473.1 0.08 0.27 25 LNU52 25721.3 0.70 0.22 18 LNU179 24632.5 0.43 0.60 10 LNU242 25471.1 0.07 0.56 12 CONT. — 0.70 — 0 LNU232 26003.3 0.53 0.06 36 LNU76 26421.2 0.09 0.13 36 LNU143 25975.3 0.81 0.31 16 LNU232 26003.7 0.50 0.11 29 LNU76 26422.2 0.07 0.69 9 LNU143 25975.2 0.81 0.31 16 LNU232 26001.5 0.46 0.35 17 LNU76 26421.1 0.07 0.76 7 LNU154 14601.6 0.96 0.18 37 LNU232 26001.2 0.45 0.39 16 LNU95 13985.15 0.08 0.21 28 LNU207 24641.1 0.86 0.30 23 LNU232 26003.6 0.44 0.47 14 LNU95 13985.11 0.08 0.33 21 LNU207 24642.5 0.83 0.22 19 LNU235 26184.4 0.50 0.13 28 CONT. — 0.07 — 0 LNU207 24642.4 0.81 0.33 16 LNU235 26185.3 0.49 0.17 25 LNU118 14013.8 0.09 0.03 36 LNU211 24771.1 0.84 0.24 21 LNU235 26184.2 0.48 0.22 23 LNU118 14013.6 0.09 0.07 29 LNU52 25723.1 0.86 0.23 24 LNU235 26182.1 0.47 0.27 20 LNU118 14012.15 0.08 0.25 19 LNU52 25721.1 0.73 0.76 5 LNU235 26185.2 0.43 0.55 11 LNU118 14012.12 0.08 0.29 16 LNU69 14571.1 0.90 0.13 30 LNU242 25473.3 0.56 0.02 43 LNU118 14012.14 0.07 0.60 9 LNU69 14573.3 0.76 0.62 9 LNU242 25474.1 0.54 0.05 39 LNU150 24842.9 0.10 0.00 54 LNU69 14572.8 0.75 0.63 8 LNU242 25471.1 0.51 0.08 32 LNU150 24841.9 0.08 0.07 28 CONT. — 0.47 — 0 LNU242 25473.1 0.51 0.09 31 LNU150 24841.6 0.07 0.69 6 LNU150 24842.9 0.83 0.00 76 LNU242 25472.1 0.41 0.73 6 LNU179 24632.7 0.08 0.09 28 LNU150 24843.5 0.79 0.00 68 LNU76 26421.2 0.55 0.04 42 LNU179 24631.7 0.08 0.20 20 LNU150 24841.9 0.74 0.00 58 LNU76 26421.1 0.49 0.14 27 LNU179 24632.5 0.07 0.68 7 LNU150 24843.9 0.62 0.06 33 LNU76 26422.2 0.43 0.57 11 LNU232 26001.5 0.09 0.06 30 LNU179 24631.9 0.71 0.00 51 LNU76 26423.1 0.43 0.58 10 LNU232 26003.3 0.07 0.51 10 LNU179 24632.5 0.56 0.24 21 LNU76 26425.1 0.42 0.66 8 LNU232 26003.6 0.07 0.65 7 LNU232 26003.7 0.82 0.00 75 LNU95 13985.11 0.53 0.07 35 LNU235 26184.4 0.12 0.00 76 LNU323 26003.3 0.68 0.01 45 LNU95 13985.15 0.50 0.12 29 LNU235 26185.2 0.09 0.01 40 LNU232 26003.6 0.51 0.64 9 LNU95 13985.19 0.48 0.19 25 LNU235 26184.2 0.09 0.02 37 LNU235 26185.3 0.63 0.05 34 LNU95 13985.16 0.48 0.22 23 LNU235 26182.1 0.07 0.67 6 LNU235 26184.4 0.62 0.07 32 LNU95 13985.12 0.46 0.34 18 LNU242 25474.1 0.08 0.12 24 LNU235 26182.1 0.54 0.35 15 CONT. — 0.44 — 0 LNU288 14563.9 0.12 0.00 76 LNU235 26184.2 0.54 0.42 15 LNU118 14013.6 0.48 0.65 9 LNU288 14562.1 0.09 0.07 31 LNU242 25474.1 0.87 0.00 86 LNU118 14012.12 0.47 0.77 6 LNU288 14563.6 0.08 0.14 23 LNU242 25471.1 0.69 0.01 47 LNU150 24842.9 0.54 0.27 22 LNU288 14564.9 0.08 0.20 23 LNU242 25473.1 0.68 0.01 46 LNU150 24843.5 0.47 0.74 6 LNU288 14562.7 0.08 0.40 14 LNU242 25473.3 0.56 0.26 19 LNU179 24632.5 0.50 0.47 13 LNU76 26421.2 0.08 0.18 21 LNU242 25472.1 0.51 0.65 8 LNU179 24631.7 0.48 0.64 9 LNU76 26423.1 0.07 0.48 11 LNU76 26421.2 0.84 0.00 80 LNU232 26001.5 0.52 0.40 16 LNU76 26422.2 0.07 0.60 8 LNU76 26421.1 0.67 0.01 43 LNU232 26003.3 0.52 0.39 16 LNU76 26425.1 0.07 0.63 8 LNU76 26422.2 0.54 0.37 15 LNU235 26185.2 0.52 0.38 16 LNU95 13985.16 0.11 0.00 66 LNU76 26425.1 0.53 0.48 13 LNU235 26184.4 0.49 0.57 11 LNU95 13985.15 0.10 0.01 44 LNU76 26423.1 0.51 0.65 8 LNU124 26184.2 0.48 0.61 9 LNU 13985.12 0.08 0.10 26 LNU95 13985.11 0.86 0.00 83 LNU235 26182.1 0.48 0.65 9 CONT. — 0.06 — 0 LNU95 13985.12 0.81 0.00 73 LNU242 25474.1 0.53 0.33 18 LNU101 27635.1 0.08 0.03 24 LNU95 13985.19 0.67 0.03 43 LNU288 14563.9 0.54 0.27 21 LNU101 27632.1 0.07 0.18 14 LNU95 13985.16 0.66 0.03 42 LNU288 14563.6 0.51 0.43 15 LNU128 26515.3 0.08 0.00 35 LNU95 13985.12 0.54 0.40 16 LNU288 14562.1 0.49 0.63 9 LNU128 26515.2 0.07 0.15 18 CONT. — 0.58 — 0 LNU288 14562.7 0.48 0.70 7 LNU192 28315.2 0.07 0.06 22 LNU118 14013.6 0.77 0.08 33 LNU76 26421.2 0.49 0.60 10 LNU192 28313.2 0.07 0.36 11 LNU118 14012.15 0.76 0.14 31 LNU76 26425.1 0.48 0.68 8 LNU211 24771.1 0.08 0.00 37 LNU118 14013.8 0.61 0.78 5 LNU95 13985.11 0.55 0.21 23 LNU282 27563.3 0.08 0.00 34 LNU150 24842.9 0.84 0.03 45 LNU95 13985.12 0.50 0.49 13 LNU69 14571.1 0.08 0.00 39 LNU150 24843.5 0.71 0.20 23 LNU95 13985.16 0.49 0.58 10 LNU69 14573.5 0.07 0.22 13 LNU150 24841.9 0.68 0.34 18 LNU95 13985.15 0.48 0.71 7 LNU69 14572.9 0.06 0.60 5 LNU179 24632.7 0.65 0.49 13 CONT. — 0.52 — 0 LNU75 27572.1 0.08 0.00 36 LNU179 24631.7 0.64 0.60 10 LNU101 27632.5 0.64 0.01 24 LNU75 27572.2 0.07 0.18 15 LNU179 24632.5 0.61 0.76 6 LNU101 27635.1 0.57 0.31 9 LNU75 27572.3 0.06 0.58 6 LNU232 26001.5 0.93 0.00 60 LNU101 27632.1 0.55 0.50 6 CONT. — 0.05 — 0 LNU232 26003.3 0.83 0.02 42 LNU101 27632.6 0.55 0.54 6 LNU101 27632.5 0.08 0.03 38 LNU235 26184.4 1.17 0.00 101 LNU128 26511.4 0.59 0.15 14 LNU118 14012.15 0.07 0.16 23 LNU235 26185.2 0.88 0.01 52 LNU128 26511.5 0.54 0.70 4 LNU118 14013.6 0.07 0.14 23 LNU235 26184.2 0.85 0.01 47 LNU192 28313.3 0.63 0.01 22 LNU118 14013.9 0.06 0.54 8 LNU235 26182.1 0.68 0.32 18 LNU192 28315.2 0.63 0.04 21 LNU206 27621.2 0.07 0.01 38 LNU242 25474.1 0.88 0.01 51 LNU192 28313.2 0.56 0.49 7 LNU206 27621.1 0.06 0.38 13 LNU288 14563.9 0.99 0.00 71 LNU206 27621.2 0.59 0.24 13 LNU249 26153.1 0.09 0.00 57 LNU288 14562.1 0.80 0.04 38 LNU282 27563.3 0.54 0.69 4 LNU282 27563.1 0.07 0.05 33 LNU288 14563.6 0.73 0.17 26 CONT. — 0.50 — 0 LNU282 27565.2 0.06 0.79 4 LNU288 14562.7 0.61 0.78 5 LNU101 27635.1 0.58 0.02 17 LNU288 14564.8 0.09 0.00 67 LNU76 26421.2 0.66 0.43 14 LNU101 27632.5 0.56 0.13 12 LNU288 14563.9 0.08 0.00 56 LNU76 26423.1 0.63 0.60 9 LNU118 14012.15 0.56 0.13 11 LNU288 14562.9 0.07 0.04 35 LNU76 26425.1 0.63 0.62 9 LNU118 14013.6 0.51 0.73 3 LNU288 14562.7 0.07 0.13 24 LNU76 26422.2 0.63 0.66 8 LNU128 26515.3 0.60 0.01 19 LNU288 14563.6 0.06 0.33 15 LNU95 13985.15 0.87 0.01 51 LNU192 28315.2 0.54 0.30 9 LNU75 27571.4 0.08 0.03 42 LNU95 13985.16 0.86 0.01 48 LNU206 27621.2 0.58 0.03 17 LNU75 27572.3 0.07 0.07 33 LNU95 13985.12 0.73 0.16 26 LNU206 27622.4 0.53 0.37 6 LNU75 27572.2 0.07 0.08 30 CONT. — 0.61 — 0 LNU249 26152.2 0.58 0.03 16 LNU75 27571.2 0.06 0.23 17 LNU101 27632.1 0.83 0.00 36 LNU249 26152.4 0.55 0.26 11 CONT. — 0.06 — 0 LNU101 27635.1 0.77 0.02 25 LNU249 26151.1 0.52 0.68 4 LNU11 28204.3 0.07 0.63 6 LNU101 27632.5 0.73 0.13 19 LNU249 26153.1 0.52 0.70 4 LNU11 28204.1 0.07 0.73 4 LNU101 27632.6 0.67 0.47 9 LNU282 27563.3 0.56 0.09 12 LNU112 28212.4 0.07 0.64 6 LNU128 26515.3 0.95 0.00 55 LNU282 27563.1 0.55 0.26 11 LNU14 27824.2 0.08 0.22 32 LNU128 26515.2 0.82 0.00 35 LNU282 27562.1 0.55 0.42 10 LNU183 24863.12 0.12 0.00 81 LNU128 26511.4 0.76 0.06 24 LNU282 27565.2 0.53 0.41 6 LNU183 24863.1 0.10 0.00 50 LNU128 26511.5 0.63 0.77 3 LNU282 27565.1 0.51 0.79 2 LNU183 24865.1 0.09 0.00 46 LNU192 28315.2 0.95 0.00 56 LNU288 14563.6 0.62 0.01 24 LNU183 24864.6 0.07 0.25 14 LNU192 28313.2 0.88 0.00 44 LNU288 14564.8 0.60 0.01 19 LNU191 28323.1 0.07 0.70 6 LNU192 28313.3 0.74 0.04 21 LNU288 14562.9 0.56 0.12 12 LNU201 28223.1 0.07 0.71 4 LNU206 27621.2 0.83 0.00 36 LNU288 14562.7 0.51 0.67 3 LNU268 26044.2 0.08 0.20 18 LNU206 27621.1 0.72 0.14 17 LNU75 27572.2 0.61 0.00 23 LNU268 26045.1 0.07 0.32 12 LNU211 24771.1 0.81 0.01 32 LNU75 27571.4 0.60 0.03 20 CONT. — 0.05 — 0 LNU282 27563.3 0.79 0.02 30 LNU75 27572.1 0.57 0.05 15 LNU11 28204.1 0.07 0.08 32 LNU69 14571.1 0.79 0.01 29 LNU75 27571.2 0.54 0.30 8 LNU11 28205.2 0.07 0.09 29 LNU69 14573.5 0.78 0.02 28 CONT. — 0.50 — 0 LNU11 28205.1 0.07 0.13 29 LNU75 27572.2 0.94 0.00 53 LNU11 28203.2 0.55 0.43 11 LNU11 28203.2 0.06 0.12 25 LNU75 27572.3 0.81 0.00 33 LNU11 28202.5 0.55 0.45 10 LNU11 28204.3 0.06 0.25 18 LNU75 27572.1 0.78 0.02 27 LNU112 28212.1 0.62 0.09 24 LNU11 28202.5 0.05 0.78 5 LNU75 27571.4 0.70 0.25 14 LNU112 28212.4 0.52 0.72 5 LNU112 28212.4 0.07 0.03 40 CONT. — 0.61 — 0 LNU14 27853.2 0.56 0.37 13 LNU112 28212.1 0.06 0.22 22 LNU101 27632.5 0.86 0.03 42 LNU14 27821.1 0.55 0.49 10 LNU112 28211.2 0.06 0.52 11 LNU101 27635.1 0.65 0.69 7 LNU183 24864.6 0.56 0.38 13 LNU14 27821.3 0.07 0.07 38 LNU118 14012.15 0.77 0.11 26 LNU201 28223.1 0.57 0.27 15 LNU14 27821.4 0.07 0.17 29 LNU118 14013.6 0.74 0.19 21 LNU201 28222.3 0.55 0.40 11 LNU14 27823.2 0.07 0.13 27 LNU118 14013.9 0.65 0.60 8 LNU201 28223.3 0.52 0.76 4 LNU183 24865.1 0.14 0.00 176 LNU206 27621.2 0.88 0.01 45 LNU268 26044.2 0.58 0.25 16 LNU183 24863.12 0.13 0.00 158 LNU249 26153.1 0.76 0.10 26 LNU268 26041.6 0.54 0.52 8 LNU183 24863.1 0.13 0.00 156 LNU249 26152.4 0.70 0.38 15 LNU268 26041.4 0.53 0.68 6 LNU183 24864.6 0.13 0.00 147 LNU282 27563.1 0.74 0.21 22 LNU268 26045.1 0.52 0.78 4 LNU183 24864.7 0.06 0.21 22 LNU282 27565.2 0.64 0.74 5 CONT. — 0.60 — 0 LNU191 28325.4 0.08 0.02 49 LNU288 14564.8 0.86 0.01 42 LNU11 28205.2 0.67 0.31 12 LNU191 28324.2 0.07 0.04 42 LNU288 14563.6 0.83 0.05 37 LNU11 28204.3 0.65 0.43 9 LNU191 28323.1 0.07 0.16 37 LNU288 14562.9 0.81 0.04 34 LNU11 28204.1 0.63 0.57 6 LNU191 28325.3 0.07 0.06 34 LNU288 14563.9 0.75 0.16 24 LNU11 28203.2 0.63 0.60 6 LNU191 28321.3 0.06 0.57 10 LNU75 27572.2 0.90 0.01 49 LNU112 28212.4 0.62 0.70 4 LNU201 28222.2 0.09 0.00 82 LNU75 27571.4 0.86 0.03 41 LNU14 27821.3 0.64 0.45 8 LNU201 28223.3 0.06 0.20 23 LNU75 27571.2 0.80 0.04 31 LNU183 24863.1 0.72 0.08 21 LNU201 28221.3 0.06 0.42 14 LNU75 27572.3 0.74 0.29 21 LNU183 24864.6 0.63 0.63 5 LNU201 28223.1 0.06 0.48 13 CONT. — 0.81 — 0 LNU201 28222.2 0.63 0.59 6 LNU201 28222.3 0.05 0.75 6 LNU14 27821.3 0.92 0.41 14 LNU268 26043.4 0.63 0.55 7 LNU268 26043.4 0.08 0.01 47 LNU183 24863.12 0.84 0.78 4 CONT. — 0.53 — 0 LNU268 26041.4 0.07 0.03 39 LNU268 26044.2 1.01 0.17 25 LNU116 14492.5 0.58 0.46 10 LNU268 26041.6 0.06 0.31 22 CONT. — 0.75 — 0 LNU121 27713.4 0.55 0.76 4 LNU268 26045.1 0.06 0.48 14 LNU11 28205.2 1.10 0.00 46 LNU126 25343.3 0.57 0.59 7 LNU268 26044.2 0.06 0.68 7 LNU11 28203.2 0.99 0.04 32 LNU158 27433.3 0.60 0.38 13 CONT. — 0.04 — 0 LNU11 28205.1 0.94 0.09 25 LNU177 24765.2 0.60 0.38 14 LNU107 14585.5 0.06 0.17 32 LNU11 28204.3 0.93 0.10 24 LNU177 24762.6 0.56 0.67 5 LNU107 14584.9 0.05 0.31 18 LNU11 28202.5 0.91 0.15 21 LNU177 24764.9 0.56 0.69 5 LNU107 14583.8 0.05 0.44 14 LNU11 28204.1 0.82 0.48 9 LNU182 25384.5 0.58 0.48 10 LNU116 14493.6 0.06 0.02 38 LNU112 28212.4 0.89 0.22 18 LNU2 27842.3 0.60 0.35 13 LNU116 14494.5 0.06 0.07 30 LNU112 28212.1 0.85 0.35 12 LNU225 25991.2 0.59 0.41 12 LNU116 14492.9 0.05 0.02 28 LNU14 27821.3 1.08 0.01 44 LNU225 25991.5 0.59 0.47 11 LNU116 14492.5 0.05 0.13 21 LNU14 27823.2 0.85 0.46 14 LNU239 26284.1 0.60 0.32 14 LNU121 25642.2 0.08 0.00 99 LNU183 24865.1 1.33 0.00 77 LNU239 26284.2 0.57 0.57 7 LNU121 27713.4 0.07 0.00 60 LNU183 24863.1 1.32 0.00 75 LNU57 27852.1 0.59 0.39 12 LNU121 27711.1 0.06 0.04 40 LNU183 24864.6 1.09 0.01 45 LNU83 27684.1 0.56 0.64 7 LNU121 27713.1 0.06 0.07 36 LNU183 24863.12 1.09 0.01 45 LNU83 27682.1 0.55 0.76 4 LNU126 25345.1 0.07 0.00 57 LNU191 28323.1 0.97 0.15 29 CONT. — 0.51 — 0 LNU126 25343.3 0.07 0.00 57 LNU191 28325.4 0.81 0.54 8 LNU107 14584.9 0.66 0.14 29 LNU126 25343.1 0.06 0.05 40 LNU201 28222.2 1.26 0.00 67 LNU107 14583.8 0.64 0.14 26 LNU158 27433.3 0.06 0.05 33 LNU201 28223.1 0.82 0.50 10 LNU107 14585.2 0.61 0.22 20 LNU158 27433.2 0.05 0.28 19 LNU268 26043.4 1.00 0.03 33 LNU107 14585.5 0.58 0.40 13 LNU158 27432.5 0.05 0.64 10 LNU268 26041.4 0.91 0.14 21 LNU116 14491.5 0.61 0.28 19 LNU177 24765.2 0.05 0.08 28 LNU268 26041.6 0.90 0.31 20 LNU116 14492.9 0.55 0.61 8 LNU177 24762.6 0.05 0.15 26 LNU268 26044.2 0.80 0.61 6 LNU121 27713.1 0.68 0.05 33 LNU177 24764.9 0.05 0.54 8 CONT. — 0.61 — 0 LNU121 27713.4 0.63 0.20 22 LNU182 25384.5 0.06 0.03 30 LNU107 14585.5 0.74 0.27 21 LNU121 27711.1 0.62 0.18 21 LNU182 27521.4 0.05 0.22 27 LNU107 14583.8 0.74 0.20 20 LNU126 25343.1 0.63 0.17 22 LNU182 25384.1 0.05 0.53 11 LNU107 14584.9 0.69 0.32 13 LNU126 25343.4 0.62 0.18 21 LNU2 25713.1 0.05 0.06 29 LNU116 14492.5 0.67 0.43 10 LNU126 25343.3 0.53 0.80 4 LNU2 27842.1 0.05 0.59 15 LNU116 14492.9 0.65 0.59 7 LNU158 27433.3 0.69 0.06 35 LNU2 27842.3 0.05 0.55 9 LNU116 14494.5 0.65 0.61 7 LNU158 27433.2 0.66 0.09 29 LNU225 25991.5 0.05 0.46 14 LNU121 27713.4 0.96 0.00 57 LNU158 27432.5 0.65 0.11 27 LNU225 25991.2 0.05 0.55 9 LNU121 25642.2 0.87 0.02 43 LNU158 27434.1 0.61 0.17 19 LNU239 26284.1 0.06 0.01 40 LNU121 27711.1 0.85 0.01 39 LNU158 27434.5 0.56 0.56 10 LNU239 26283.2 0.05 0.41 12 LNU121 27713.1 0.69 0.34 12 LNU177 24763.6 0.68 0.07 33 LNU239 26281.1 0.05 0.63 6 LNU126 25345.1 0.89 0.00 46 LNU177 24764.12 0.66 0.07 29 LNU57 27852.1 0.05 0.23 15 LNU126 25343.3 0.80 0.02 31 LNU177 24765.2 0.64 0.12 25 LNU57 27854.3 0.05 0.35 12 LNU126 25343.1 0.75 0.14 23 LNU177 24764.9 0.58 0.38 14 CONT. — 0.03 — 0 LNU158 27433.3 1.04 0.01 71 LNU182 25384.2 0.67 0.08 31 LNU107 14584.9 0.06 0.00 151 LNU158 27433.2 0.94 0.00 54 LNU182 25384.1 0.60 0.24 18 LNU107 14585.2 0.05 0.02 105 LNU158 27432.5 0.71 0.37 16 LNU182 25384.5 0.59 0.30 16 LNU107 14585.5 0.04 0.09 64 LNU177 24762.6 1.04 0.00 71 LNU182 25384.6 0.59 0.37 16 LNU107 14583.8 0.04 0.31 41 LNU177 24765.2 0.83 0.11 35 LNU182 27521.4 0.55 0.63 8 LNU107 14583.1 0.03 0.35 34 LNU177 24764.9 0.69 0.28 13 LNU2 27842.1 0.65 0.14 26 LNU116 14492.5 0.06 0.01 126 LNU182 25384.5 0.91 0.01 49 LNU2 27842.3 0.62 0.20 21 LNU116 14493.6 0.05 0.05 81 LNU182 27521.4 0.84 0.02 38 LNU2 25713.1 0.58 0.36 13 LNU116 14491.5 0.05 0.10 77 LNU182 25384.1 0.80 0.03 31 LNU225 25991.3 0.65 0.12 28 LNU116 14494.5 0.03 0.59 26 LNU2 27842.3 0.90 0.01 47 LNU225 25991.2 0.62 0.21 22 LNU116 14492.9 0.03 0.72 15 LNU2 25713.1 0.85 0.01 39 LNU225 25991.5 0.62 0.22 21 LNU121 27713.4 0.09 0.00 258 LNU2 27842.1 0.77 0.31 26 LNU225 25991.8 0.59 0.34 16 LNU121 27713.1 0.06 0.01 145 LNU225 25991.5 1.09 0.00 78 LNU239 26283.3 0.59 0.33 16 LNU121 27713.3 0.05 0.01 113 LNU225 25991.2 0.81 0.05 32 LNU239 26284.1 0.58 0.37 14 LNU121 25642.2 0.05 0.01 99 LNU225 25991.1 0.75 0.15 22 LNU239 26281.1 0..58 0.42 14 LNU121 27711.1 0.05 0.10 79 LNU225 25991.3 0.68 0.55 12 LNU239 26284.2 0.54 0.70 6 LNU126 25343.1 0.05 0.01 111 LNU239 26284.1 0.78 0.06 28 LNU57 27854.5 0.66 0.11 29 LNU126 25343.3 0.04 0.14 66 LNU239 26283.2 0.68 0.48 12 LNU57 27852.1 0.64 0.12 26 LNU126 25343.4 0.03 0.53 20 LNU239 26281.1 0.67 0.48 9 LNU57 27851.2 0.63 0.16 23 LNU126 25345.1 0.03 0.53 19 LNU57 27852.1 0.92 0.00 50 LNU57 27854.3 0.59 0.29 16 LNU158 27432.5 0.07 0.00 170 LNU57 27854.3 0.71 0.25 16 LNU83 27685.1 0.71 0.05 39 LNU158 27433.3 0.07 0.00 159 LNU57 27854.5 0.68 0.39 12 LNU83 27682.1 0.66 0.11 30 LNU158 27433.2 0.05 0.02 105 LNU83 27681.4 0.85 0.02 38 LNU83 27685.2 0.66 0.08 29 LNU158 27434.1 0.03 0.56 21 LNU83 27684.1 0.66 0.60 8 LNU83 27681.4 0.59 0.34 15 LNU158 27434.5 0.03 0.67 16 LNU83 27685.1 0.64 0.78 4 LNU83 27684.1 0.58 0.39 14 LNU177 24762.6 0.04 0.09 60 CONT. — 0.58 — 0 LNU177 24764.12 0.03 0.41 30 LNU107 14584.9 1.26 0.00 118 LNU177 24763.6 0.03 0.51 26 LNU107 14583.8 0.96 0.00 66 LNU182 25384.1 0.05 0.02 103 LNU107 14585.2 0.84 0.00 45 LNU182 25384.6 0.05 0.04 101 LNU107 14583.1 0.64 0.40 11 LNU182 25384.2 0.04 0.08 72 LNU107 14585.5 0.63 0.56 8 LNU182 25384.5 0.03 0.43 31 LNU116 14493.6 0.91 0.00 56 LNU182 27521.4 0.03 0.76 11 LNU116 14494.5 0.86 0.02 48 LNU2 27845.3 0.05 0.02 105 LNU116 14491.5 0.86 0.03 48 LNU2 25713.1 0.05 0.04 95 LNU116 14492.5 0.73 0.06 26 LNU2 27842.3 0.05 0.09 85 LNU116 14492.9 0.63 0.64 9 LNU2 27842.1 0.04 0.09 72 LNU121 27713.4 1.28 0.00 120 LNU2 27845.2 0.03 0.46 30 LNU121 27713.1 1.13 0.00 95 LNU225 25991.2 0.08 0.00 207 LNU121 27711.1 0.85 0.01 47 LNU225 25991.3 0.05 0.03 110 LNU121 25642.2 0.70 0.23 20 LNU225 25991.1 0.05 0.05 80 LNU126 25343.1 0.85 0.02 46 LNU225 25991.8 0.04 0.12 68 LNU126 25343.4 0.68 0.24 17 LNU225 25991.5 0.03 0.58 19 LNU126 25343.3 0.66 0.35 14 LNU239 26284.2 0.05 0.02 102 LNU126 25345.1 0.63 0.56 9 LNU239 26281.1 0.04 0.11 71 LNU158 27433.3 1.25 0.00 117 LNU239 26283.2 0.04 0.11 67 LNU158 27432.5 1.22 0.00 110 LNU239 26283.3 0.04 0.27 53 LNU158 27433.2 0.88 0.00 52 LNU239 26284.1 0.04 0.27 44 LNU158 27434.5 0.84 1.01 46 LNU57 27852.1 0.05 0.07 81 LNU158 27434.1 0.71 0.15 23 LNU57 27851.2 0.04 0.08 62 LNU177 24764.12 0.96 0.00 65 LNU57 27854.5 0.03 0.43 27 LNU177 24763.6 0.82 0.01 42 LNU83 27685.1 0.05 0.04 110 LNU177 24765.2 0.63 0.58 9 LNU83 27685.2 0.05 0.03 91 LNU182 25384.6 1.03 0.00 78 LNU83 27681.4 0.04 0.17 53 LNU182 25384.1 0.91 0.00 58 LNU83 27682.1 0.03 0.41 34 LNU182 25384.2 0.84 0.01 46 LNU83 27684.1 0.03 0.69 16 LNU182 27521.4 0.71 0.16 23 LNU182 25384.5 0.70 0.18 21 LNU2 27842.1 0.98 0.00 69 LNU2 27842.3 0.95 0.00 64 LNU2 25713.1 0.89 0.02 54 LNU2 27845.2 0.68 0.27 18 LNU225 25991.2 1.35 0.00 133 LNU225 25991.3 1.27 0.00 119 LNU225 25991.8 0.87 0.01 50 LNU225 25991.1 0.82 0.00 42 LNU225 25991.5 0.82 0.01 41 LNU239 26283.3 0.88 0.01 51 LNU239 26281.1 0.82 0.02 42 LNU239 26284.2 0.70 0.15 20 LNU239 26284.1 0.66 0.33 14 LNU239 26283.2 0.65 0.36 12 LNU57 27854.5 1.11 0.00 92 LNU57 27851.2 1.11 0.00 91 LNU57 27852.1 1.08 0.00 86 LNU57 27854.3 0.69 0.16 19 LNU83 27685.1 1.10 0.00 89 LNU83 27685.2 1.02 0.00 76 LNU83 27682.1 0.88 0.01 51 LNU83 27681.4 0.83 0.00 43 LNU83 27684.1 0.68 0.35 17 Table 76. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment. “RGR” = relative growth rate;

TABLE 77 Genes showing improved growth rate at standard nitrogen growth conditions (T1 generation) RGR Of Leaf Area RGR Of Roots Coverage RGR Of Roots Length Gene p- % Gene p- % Gene p- % Name Ave. value incr. Name Ave. value incr. Name Ave. value incr. CONT. 0.064 — 0.0 CONT. 0.308 — 0.0 CONT. 0.401 — 0 LNU121 0.070 0.313 8.9 LNU121 0.498 0.000 61.7 LNU121 0.480 0.002 19.8 CONT. 0.065 — 0.0 LNU154 0.341 0.475 10.6 LNU154 0.402 0.971 0.36 LNU275 0.103 0.000 59.6 LNU210 0.339 0.326 10.2 LNU210 0.417 0.531 4 LNU57 0.073 0.309 13.4 CONT. 0.322 — 0.0 CONT. 0.386 — 0 LNU64 0.068 0.723 4.5 LNU275 0.862 0.000 167.2 LNU275 0.509 0.002 32 LNU83 0.084 0.033 29.3 LNU57 0.535 0.000 66.0 LNU57 0.515 0.000 34 CONT. 0.063 — 0.0 LNU58 0.387 0.154 20.1 LNU58 0.407 0.473 5.7 LNU59 0.065 0.738 3.5 LNU83 0.549 0.000 70.2 LNU64 0.388 0.954 0.5 CONT. 0.229 — 0.0 CONT. 0.186 — 0.0 LNU83 0.528 0.000 37 LNU222_H6 0.258 0.65  13 LNU176 0.250 0.043 34.6 CONT. 0.326 — 0 LNU214 0.219 0.210 18.2 LNU176 0.371 0.101 14 LNU223 0.234 0.060 26.2 LNU214 0.368 0.120 13 LNU233 0.230 0.129 23.9 LNU223 0.364 0.097 12 LNU245 0.200 0.513 7.7 LNU233 0.372 0.061 14 LNU247 0.187 0.961 0.7 LNU245 0.375 0.045 16 LNU284 0.222 0.220 19.5 LNU247 0.335 0.745 3 LNU289 0.241 0.020 30.1 LNU284 0.377 0.105 16 LNU70 0.247 0.038 32.9 LNU289 0.366 0.086 13 LNU85 0.256 0.013 38.2 LNU70 0.377 0.112 16 CONT. 0.380 — 0.0 LNU85 0.416 0.002 28 LNU105 0.400 0.710 5.2 CONT. 0.413 — 0 LNU115 0.432 0.278 13.6 LNU105 0.446 0.325 8.1 LNU134 0.434 0.339 14.2 LNU115 0.455 0.168 10 LNU198 0.385 0.925 1.2 LNU134 0.446 0.328 8 LNU200 0.391 0.820 3.0 LNU198 0.415 0.966 0.4 CONT. 0.388 — 0.0 CONT. 0.468 — 0 LNU51 0.395 0.870 1.8 LNU225 0.478 0.756 2.3 LNU59 0.402 0.703 3.7 LNU51 0.488 0.541 4.5 CONT. 0.429 LNU59 0.502 0.320 7.3 LNU258 0.522 0.25  21.7 Table 77. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment; “RGR” = relative growth rate.

Example 15 Evaluation of Transgenic Arabidopsis NUE, Yield and Plant Growth Rate Under Low or Normal Nitrogen Fertilization in Greenhouse Assay

Assay 1: Nitrogen Use efficiency: Seed yield plant biomass and plant growth rate at limited and optimal nitrogen concentration under greenhouse conditions—This assay follows seed yield production, the biomass formation and the rosette area growth of plants grown in the greenhouse at limiting and non-limiting nitrogen growth conditions. Transgenic Arabidopsis seeds were sown in agar media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:1 ratio. The trays were irrigated with a solution containing nitrogen limiting conditions, which were achieved by irrigating the plants with a solution containing 1.5 mM inorganic nitrogen in the form of KNO₃, supplemented with 1 mM KH₂PO₄, 1 mM MgSO₄, 3.6 mM KCl, 2 mM CaCl₂ and microelements, while normal nitrogen levels were achieved by applying a solution of 6 mM inorganic nitrogen also in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, 2 mM CaCl₂ and microelements. All plants were grown in the greenhouse until mature seeds. Seeds were harvested, extracted and weight. The remaining plant biomass (the above ground tissue) was also harvested, and weighted immediately or following drying in oven at 50° C. for 24 hours.

Each construct was validated at its T₂ generation. Transgenic plants transformed with a construct conformed by an empty vector carrying the 35S promoter and the selectable marker was used as control.

The plants were analyzed for their overall size, growth rate, flowering, seed yield, 1,000-seed weight, dry matter and harvest index (HI— seed yield/dry matter). Transgenic plants performance was compared to control plants grown in parallel under the same conditions. Mock-transgenic plants expressing the uidA reporter gene (GUS-Intron) or with no gene at all, under the same promoter were used as control.

The experiment was planned in nested randomized plot distribution. For each gene of the invention three to five independent transformation events were analyzed from each construct.

Digital imaging—A laboratory image acquisition system, which consists of a digital reflex camera (Canon EOS 300D) attached with a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which includes 4 light units (4×150 Watts light bulb) is used for capturing images of plant samples.

The image capturing process is repeated every 2 days starting from day 1 after transplanting till day 15. Same camera, placed in a custom made iron mount, is used for capturing images of larger plants sawn in white tubs in an environmental controlled greenhouse. The tubs are square shape include 1.7 liter trays. During the capture process, the tubs are placed beneath the iron mount, while avoiding direct sun light and casting of shadows.

An image analysis system is used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.39 [Java based image processing program which was developed at the U.S. National Institutes of Health and freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/]. Images are captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data is saved to text files and processed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data is calculated, including leaf number, rosette area, rosette diameter, leaf blade area.

Vegetative growth rate: the relative growth rate (RGR) of leaf number [formula X (described above)], rosette area (formula XV), plot coverage (formula XVI) and harvest index (formula IV) is calculated with the indicated formulas.

Relative growth rate of rosette area=Regression coefficient of rosette area along time course.  Formula XV:

Relative growth rate of plot coverage=Regression coefficient of plot coverage along time course.  Formula XVI

Seeds average weight—At the end of the experiment all seeds are collected. The seeds are scattered on a glass tray and a picture was taken. Using the digital analysis, the number of seeds in each sample is calculated.

Dry weight and seed yield—On about day 80 from sowing, the plants are harvested and left to dry at 30° C. in a drying chamber. The biomass and seed weight of each plot are measured and divided by the number of plants in each plot. Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 30° C. in a drying chamber; Seed yield per plant=total seed weight per plant (gr). 1000 seed weight (the weight of 1000 seeds) (gr.).

The harvest index (HI) was calculated using Formula IV as described above.

Oil percentage in seeds—At the end of the experiment all seeds from each plot are collected. Seeds from 3 plots are mixed grounded and then mounted onto the extraction chamber. 210 ml of n-Hexane (Cat No. 080951 Biolab Ltd.) are used as the solvent. The extraction is performed for 30 hours at medium heat 50° C. Once the extraction has ended the n-Hexane was evaporated using the evaporator at 35° C. and vacuum conditions. The process is repeated twice. The information gained from the Soxhlet extractor (Soxhlet, F. Die gewichtsanalytische Bestimmung des Milchfettes, Polytechnisches J. (Dingler's) 1879, 232, 461) is used to create a calibration curve for the Low Resonance NMR. The content of oil of all seed samples is determined using the Low Resonance NMR (MARAN Ultra-Oxford Instrument) and its MultiQuant software package

Silique length analysis—On day 50 from sowing, 30 siliques from different plants in each plot are sampled in block A. The chosen siliques are green-yellow in color and are collected from the bottom parts of a grown plant's stem. A digital photograph is taken to determine silique's length.

Statistical analyses—To identify genes conferring significantly improved tolerance to abiotic stresses, the results obtained from the transgenic plants are compared to those obtained from control plants. To identify outperforming genes and constructs, results from the independent transformation events tested are analyzed separately. Data is analyzed using Student's t-test and results are considered significant if the p value was less than 0.1. The JMP statistics software package is used (Version 5.2.1, SAS Institute Inc., Cary, N.C., USA).

Example 16 Evaluation of Transgenic Arabidopsis NUE, Yield and Plant Growth Rate Under Low or Normal Nitrogen Fertilization in Greenhouse Assay

Assay 2: Nitrogen Use efficiency measured until bolting stage: plant biomass and plant growth rate at limited and optimal nitrogen concentration under greenhouse conditions—This assay follows the plant biomass formation and the rosette area growth of plants grown in the greenhouse at limiting and non-limiting nitrogen growth conditions. Transgenic Arabidopsis seeds were sown in agar media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:1 ratio. The trays were irrigated with a solution containing nitrogen limiting conditions, which were achieved by irrigating the plants with a solution containing 1.5 mM inorganic nitrogen in the form of KNO₃, supplemented with 1 mM KH₂PO₄, 1 mM MgSO₄, 3.6 mM KCl, 2 mM CaCl₂ and microelements, while normal nitrogen levels were achieved by applying a solution of 6 mM inorganic nitrogen also in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, 2 mM CaCl₂ and microelements. All plants were grown in the greenhouse until mature seeds. Plant biomass (the above ground tissue) was weight in directly after harvesting the rosette (plant fresh weight [FW]). Following plants were dried in an oven at 50° C. for 48 hours and weighted (plant dry weight [DW]).

Each construct was validated at its T₂ generation. Transgenic plants transformed with a construct conformed by an empty vector carrying the 35S promoter and the selectable marker was used as control.

The plants were analyzed for their overall size, growth rate, fresh weight and dry matter. Transgenic plants performance was compared to control plants grown in parallel under the same conditions. Mock-transgenic plants expressing the uidA reporter gene (GUS-Intron) or with no gene at all, under the same promoter were used as control.

The experiment was planned in nested randomized plot distribution. For each gene of the invention three to five independent transformation events were analyzed from each construct.

Digital imaging—A laboratory image acquisition system, which consists of a digital reflex camera (Canon EOS 300D) attached with a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which includes 4 light units (4×150 Watts light bulb) was used for capturing images of plant samples.

The image capturing process was repeated every 2 days starting from day 1 after transplanting till day 15. Same camera, placed in a custom made iron mount, was used for capturing images of larger plants sawn in white tubs in an environmental controlled greenhouse. The tubs were square shape include 1.7 liter trays. During the capture process, the tubes were placed beneath the iron mount, while avoiding direct sun light and casting of shadows.

An image analysis system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.39 [Java based image processing program which was developed at the U.S. National Institutes of Health and freely available on the internet at Hypertext Transfer Protocol://rsbweb (dot) nih (dot) gov/]. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data was calculated, including leaf number, rosette area, rosette diameter, leaf blade area.

Vegetative growth rate: the relative growth rate (RGR) of leaf number (Formula X, described above), rosette area (Formula XV described above) and plot coverage (Formula XVI, described above) are calculated using the indicated formulas.

Plant Fresh and Dry weight—On about day 80 from sowing, the plants were harvested and directly weight for the determination of the plant fresh weight (FW) and left to dry at 50° C. in a drying chamber for about 48 hours before weighting to determine plant dry weight (DW).

Statistical analyses—To identify genes conferring significantly improved tolerance to abiotic stresses, the results obtained from the transgenic plants were compared to those obtained from control plants. To identify outperforming genes and constructs, results from the independent transformation events tested were analyzed separately. Data was analyzed using Student's t-test and results are considered significant if the p value was less than 0.1. The JMP statistics software package was used (Version 5.2.1, SAS Institute Inc., Cary, N.C., USA).

Experimental Results:

The genes listed in Tables 78 and 79 improved plant NUE when grown at limiting nitrogen concentration levels. These genes produced larger plants with a larger photosynthetic area, biomass (fresh weight, dry weight, rosette diameter, rosette area and plot coverage) when grown under limiting nitrogen conditions. The genes were cloned under the regulation of a constitutive (At6669) and root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant

TABLE 78 Genes showing improved plant biomass production at limiting nitrogen growth conditions Dry Weight [g] Fresh Weight [g] Gene P- % Gene P- % Name Event # Ave. Value incr. Name Event # Ave. Value incr. CONT. — 0.139 — 0.0 CONT. — 0.890 — 0.0 LNU100 14471.4 0.157 0.252 12.8 LNU104 25032.2 0.956 0.646 7.4 LNU104 25032.2 0.160 0.429 15.0 LNU106 14481.1 0.981 0.117 10.2 LNU104 25033.3 0.156 0.439 11.9 LNU106 14483.5 0.981 0.664 10.2 LNU106 14483.5 0.163 0.499 16.8 LNU114 25042.1 1.000 0.461 12.3 LNU106 14483.2 0.162 0.637 16.4 LNU155 14525.1 0.975 0.648 9.5 LNU106 14481.1 0.160 0.084 15.0 LNU213 24654.4 0.975 0.028 9.5 LNU106 14484.3 0.146 0.658 4.7 LNU218 24781.4 0.919 0.410 3.2 LNU114 25042.1 0.166 0.483 19.0 LNU23 25163.6 0.919 0.710 3.2 LNU155 14525.1 0.169 0.360 21.3 LNU23 25163.2 0.913 0.610 2.5 LNU213 24654.4 0.168 0.222 20.8 LNU28 25171.2 1.000 0.008 12.3 LNU218 24781.4 0.156 0.134 12.3 LNU4 25134.1 0.956 0.430 7.4 LNU23 25163.6 0.159 0.032 14.1 LNU40 24792.1 0.994 0.670 11.6 LNU23 25163.2 0.156 0.333 12.3 LNU40 24794.4 0.946 0.664 6.3 LNU23 25163.5 0.148 0.677 6.0 LNU46 14462.5 0.988 0.329 10.9 LNU28 25171.2 0.169 0.004 21.3 LNU46 14462.1 0.975 0.190 9.5 LNU28 25171.1 0.146 0.395 4.7 LNU48 24804.4 0.963 0.502 8.1 LNU4 25134.1 0.164 0.007 18.1 LNU63 24814.2 1.056 0.077 18.6 LNU4 25131.1 0.159 0.146 14.1 LNU63 24811.2 1.050 0.606 17.9 LNU4 25133.3 0.146 0.374 5.1 LNU7 25082.7 0.956 0.116 7.4 LNU40 24794.4 0.164 0.399 17.8 LNU8 25062.2 1.019 0.009 14.4 LNU40 24792.1 0.155 0.607 11.4 LNU94 24833.1 0.969 0.502 8.8 LNU40 24794.3 0.151 0.254 8.7 LNU94 24834.4 0.946 0.742 6.2 LNU40 24792.2 0.148 0.782 6.7 LNU96 25073.3 0.956 0.335 7.4 LNU46 14462.5 0.172 0.487 23.5 CONT. — 0.761 — 0.0 LNU46 14464.4 0.148 0.461 6.5 LNU113 25631.3 0.900 0.458 18.3 LNU46 14462.1 0.146 0.699 5.1 LNU113 25631.7 0.894 0.196 17.5 LNU48 24804.4 0.159 0.209 14.6 LNU113 25631.9 0.875 0.032 15.0 LNU48 24801.4 0.146 0.584 4.7 LNU113 25631.4 0.863 0.232 13.4 LNU63 24811.2 0.184 0.571 32.5 LNU113 25631.1 0.813 0.149 6.8 LNU63 24814.2 0.168 0.222 20.8 LNU120 25463.3 1.119 0.016 47.1 LNU7 25082.7 0.142 0.765 2.0 LNU120 25465.3 0.856 0.204 12.6 LNU8 25062.2 0.170 0.276 22.2 LNU124 14501.1 0.813 0.475 6.8 LNU8 25061.2 0.159 0.721 14.6 LNU124 14502.1 0.794 0.388 4.4 LNU8 25063.1 0.149 0.503 7.4 LNU124 14504.5 0.788 0.439 3.5 LNU94 24833.1 0.161 0.205 15.9 LNU132 14102.6 1.013 0.141 33.1 LNU94 24834.4 0.161 0.651 15.9 LNU132 14102.7 0.906 0.345 19.2 LNU94 24833.3 0.147 0.413 5.7 LNU140 14112.6 0.931 0.000 22.4 LNU96 25073.3 0.163 0.341 17.3 LNU140 14111.6 0.844 0.139 10.9 LNU96 25071.2 0.149 0.707 7.4 LNU148 25685.6 0.906 0.174 19.2 LNU96 25073.4 0.147 0.602 5.6 LNU148 25685.2 0.881 0.057 15.9 CONT. — 0.122 — 0.0 LNU148 25685.1 0.831 0.046 9.3 LNU113 25631.7 0.146 0.446 20.1 LNU148 25685.9 0.813 0.475 6.8 LNU113 25631.3 0.133 0.620 9.4 LNU287 24674.6 1.006 0.270 32.3 LNU113 25631.1 0.131 0.398 7.3 LNU287 24674.3 0.775 0.732 1.9 LNU120 25463.3 0.173 0.184 41.7 LNU37 14064.7 0.775 0.653 1.9 LNU120 25463.7 0.125 0.732 2.6 LNU5 14042.7 0.869 0.168 14.2 LNU132 14102.7 0.143 0.245 17.6 LNU5 14043.7 0.788 0.529 3.5 LNU132 14102.6 0.140 0.451 15.0 LNU72 24962.3 0.800 0.264 5.2 LNU140 14112.6 0.149 0.329 22.7 LNU74 25443.3 0.956 0.259 25.7 LNU148 25685.6 0.144 0.002 18.6 LNU82 24823.1 0.850 0.014 11.8 LNU148 25685.2 0.138 0.321 13.0 LNU84 25621.8 0.831 0.790 9.3 LNU148 25685.9 0.129 0.199 6.3 LNU84 25621.2 0.794 0.498 4.4 LNU148 25685.1 0.127 0.651 4.2 LNU87 24712.1 0.869 0.657 14.2 LNU287 24674.6 0.156 0.008 28.4 LNU87 24711.3 0.825 0.542 8.5 LNU74 25443.3 0.151 0.071 24.2 LNU87 24713.2 0.794 0.318 4.4 LNU74 25443.5 0.138 0.626 13.0 LNU87 24714.3 0.794 0.756 4.4 LNU74 25444.1 0.135 0.209 10.9 LNU98 25761.6 0.900 0.422 18.3 LNU74 25443.2 0.126 0.521 3.2 LNU98 25762.2 0.794 0.756 4.4 LNU82 24823.1 0.152 0.303 24.8 CONT. — 0.974 — 0.0 LNU84 25621.8 0.146 0.652 19.6 LNU84 25621.2 1.031 0.280 5.9 LNU84 25621.2 0.128 0.540 4.7 CONT. — 0.851 — 0.0 LNU87 24712.1 0.148 0.595 21.2 LNU117 25933.3 1.113 0.657 30.8 LNU87 24714.3 0.143 0.613 17.1 LNU117 25931.2 1.050 0.004 23.4 LNU87 24712.4 0.126 0.762 3.7 LNU117 25932.4 0.975 0.272 14.6 LNU87 24713.2 0.124 0.757 2.2 LNU122 25333.2 1.481 0.233 74.1 LNU98 25761.6 0.132 0.543 8.3 LNU122 25332.2 1.181 0.387 38.9 LNU98 25762.2 0.131 0.639 7.8 LNU122 25333.1 1.031 0.101 21.2 LNU98 25763.2 0.125 0.722 2.7 LNU125 25944.3 1.256 0.343 47.7 CONT. — 0.129 — 0.0 LNU125 25941.4 1.244 0.381 46.2 LNU82 24823.1 0.144 0.134 11.9 LNU125 25941.2 1.081 0.443 27.1 LNU84 25621.2 0.149 0.002 15.3 LNU138 14074.5 1.488 0.001 74.9 LNU98 25763.2 0.133 0.619 3.2 LNU138 14071.5 1.425 0.157 67.5 CONT. — 0.124 — 0.0 LNU138 14074.6 1.413 0.048 66.1 LNU117 25933.3 0.160 0.692 29.2 LNU138 14072.8 1.244 0.394 46.2 LNU117 25931.2 0.135 0.237 9.0 LNU138 14072.5 1.138 0.422 33.7 LNU122 25333.2 0.228 0.287 84.3 LNU180 24724.1 1.200 0.533 41.1 LNU122 25332.2 0.180 0.412 45.4 LNU180 24721.4 1.119 0.135 31.5 LNU122 25333.1 0.144 0.003 16.1 LNU180 24721.2 1.100 0.043 29.3 LNU125 25944.3 0.179 0.470 44.9 LNU180 24722.2 0.944 0.039 11.0 LNU125 25941.4 0.179 0.500 44.4 LNU180 24723.1 0.881 0.361 3.6 LNU125 25941.2 0.157 0.624 26.7 LNU220 25405.1 1.038 0.453 22.0 LNU138 14074.5 0.224 0.031 81.2 LNU220 25405.3 0.969 0.699 13.9 LNU138 14071.5 0.216 0.199 74.7 LNU220 25405.5 0.931 0.368 9.5 LNU138 14074.6 0.205 0.091 65.6 LNU230 25413.1 1.338 0.437 57.2 LNU138 14072.8 0.169 0.584 36.3 LNU230 25412.2 1.212 0.205 42.4 LNU138 14072.5 0.147 0.695 18.6 LNU230 25413.2 1.019 0.475 19.8 LNU180 24724.1 0.180 0.575 45.4 LNU230 25412.1 0.913 0.311 7.3 LNU180 24721.4 0.159 0.346 28.2 LNU234 25014.5 1.544 0.386 81.5 LNU180 24721.2 0.151 0.119 22.2 LNU234 25014.4 1.056 0.657 24.2 LNU220 25405.3 0.148 0.660 19.1 LNU234 25014.8 1.013 0.706 19.0 LNU220 25405.1 0.143 0.642 15.6 LNU25 14083.7 1.100 0.429 29.3 LNU230 25413.1 0.193 0.512 55.5 LNU25 14084.6 1.038 0.606 22.0 LNU230 25412.2 0.183 0.218 47.5 LNU25 14082.8 0.981 0.466 15.4 LNU230 25413.2 0.149 0.654 20.1 LNU254 25782.5 1.463 0.185 71.9 LNU230 25412.1 0.134 0.269 8.0 LNU254 25781.3 1.256 0.328 47.7 LNU234 25014.5 0.221 0.492 78.2 LNU254 25782.4 1.094 0.559 28.6 LNU234 25014.4 0.152 0.664 22.7 LNU254 25781.5 0.969 0.024 13.9 LNU234 25014.8 0.151 0.725 21.7 LNU263 25794.6 1.138 0.366 33.7 LNU25 14084.6 0.154 0.634 24.2 LNU263 25794.3 1.106 0.003 30.1 LNU25 14083.7 0.148 0.668 19.1 LNU263 25791.3 1.069 0.339 25.6 LNU254 25782.5 0.226 0.199 82.2 LNU263 25794.8 0.956 0.030 12.4 LNU254 25782.4 0.171 0.547 37.8 LNU263 25792.2 0.869 0.680 2.1 LNU254 25781.3 0.166 0.527 34.3 LNU267 25804.3 1.269 0.334 49.2 LNU254 25781.5 0.129 0.138 4.5 LNU267 25803.1 1.106 0.003 30.1 LNU263 25794.6 0.163 0.456 31.3 LNU271 25912.1 1.150 0.626 35.2 LNU263 25794.8 0.138 0.011 11.6 LNU271 25913.3 1.119 0.529 31.5 LNU263 25794.3 0.138 0.018 11.1 LNU278 25812.3 0.913 0.311 7.3 LNU263 25791.3 0.129 0.765 4.5 LNU278 25814.1 0.900 0.140 5.8 LNU267 25804.3 0.197 0.323 59.0 LNU278 25814.3 0.900 0.252 5.8 LNU267 25803.1 0.156 0.034 26.2 LNU278 25813.2 0.888 0.660 4.3 LNU267 25804.4 0.134 0.759 8.0 LNU36 25561.2 1.250 0.571 47.0 LNU271 25913.3 0.168 0.604 35.8 LNU36 25562.3 1.050 0.519 23.4 LNU271 25912.1 0.167 0.666 34.9 LNU36 25562.4 0.938 0.665 10.2 LNU278 25814.3 0.129 0.708 4.0 LNU36 25562.9 0.925 0.548 8.7 LNU278 25812.3 0.126 0.674 1.5 LNU43 14422.8 1.156 0.394 35.9 LNU36 25561.2 0.193 0.589 55.5 LNU43 14421.1 1.150 0.219 35.2 LNU36 25562.3 0.149 0.429 20.1 LNU43 14423.6 0.938 0.207 10.2 LNU36 25562.4 0.138 0.749 11.6 LNU45 25052.11 1.050 0.538 23.4 LNU43 14421.1 0.159 0.254 28.2 LNU45 25052.9 0.931 0.786 9.5 LNU43 14422.8 0.159 0.580 28.2 LNU45 25052.12 0.906 0.797 6.5 LNU67 25824.5 0.156 0.585 26.2 LNU67 25824.5 1.194 0.287 40.3 LNU67 25824.3 0.154 0.513 24.7 LNU67 25824.3 1.050 0.600 23.4 CONT. — 0.179 — 0.0 LNU67 25821.5 0.900 0.252 5.8 LNU100 14474.2 0.222 0.512 24.2 CONT. — 1.058 — 0.0 LNU104 25033.3 0.213 0.558 19.3 LNU100 14474.2 1.325 0.357 25.2 LNU106 14483.2 0.232 0.720 29.8 LNU100 14473.3 1.269 0.718 19.9 LNU114 25041.2 0.215 0.661 20.4 LNU100 14472.1 1.144 0.663 8.1 LNU117 25932.4 0.363 0.306 103.3 LNU104 25033.3 1.288 0.462 21.7 LNU180 24723.1 0.341 0.543 90.7 LNU106 14483.2 1.369 0.687 29.4 LNU218 24781.2 0.278 0.651 55.7 LNU114 25041.2 1.206 0.671 14.0 LNU218 24781.1 0.227 0.359 27.0 LNU117 25932.4 1.931 0.268 82.5 LNU254 25781.3 0.333 0.021 86.1 LNU180 24723.1 1.844 0.530 74.3 LNU254 25782.5 0.217 0.285 21.4 LNU218 24781.2 1.450 0.684 37.1 LNU4 25133.3 0.256 0.106 43.4 LNU218 24781.1 1.406 0.410 32.9 LNU4 25134.2 0.193 0.707 8.1 LNU254 25781.3 1.750 0.038 65.4 LNU40 24794.3 0.259 0.557 45.2 LNU254 25782.5 1.181 0.425 11.7 LNU40 24793.1 0.254 0.522 42.4 LNU4 25133.3 1.400 0.093 32.3 LNU63 24814.7 0.333 0.446 86.1 LNU4 25134.3 1.206 0.509 14.0 LNU63 24814.2 0.283 0.221 58.5 LNU4 25134.2 1.163 0.479 9.9 LNU63 24812.3 0.256 0.305 43.4 LNU40 24794.3 1.544 0.515 45.9 LNU7 25082.2 0.197 0.697 10.2 LNU40 24793.1 1.431 0.486 35.3 LNU7 25083.3 0.189 0.753 5.7 LNU40 24792.1 1.231 0.695 16.4 LNU8 25063.6 0.193 0.669 7.8 LNU48 24803.2 1.144 0.774 8.1 CONT. — 0.106 — 0.0 LNU48 24802.2 1.139 0.581 7.7 LNU122 25332.2 0.119 0.161 11.8 LNU63 24814.7 1.813 0.453 71.3 LNU122 25333.2 0.113 0.223 5.9 LNU63 24814.2 1.613 0.140 52.4 LNU125 25941.4 0.126 0.010 18.2 LNU63 24812.3 1.494 0.216 41.2 LNU125 25943.2 0.121 0.009 13.5 LNU7 25082.2 1.206 0.354 14.0 LNU138 14072.5 0.114 0.426 7.6 LNU7 25083.3 1.169 0.454 10.5 LNU178 14612.1 0.127 0.001 19.4 LNU7 25083.1 1.144 0.696 8.1 LNU178 14614.5 0.124 0.302 16.5 LNU8 25063.6 1.231 0.319 16.4 LNU220 25405.1 0.116 0.533 8.8 CONT. — 0.690 — 0.0 LNU220 25405.5 0.114 0.260 7.6 LNU122 25332.2 0.775 0.505 12.4 LNU220 25405.6 0.108 0.798 1.2 LNU125 25941.4 0.775 0.586 12.4 LNU234 25014.6 0.128 0.076 20.6 LNU178 14612.1 0.838 0.235 21.4 LNU236 25425.4 0.134 0.302 25.9 LNU178 14614.5 0.781 0.147 13.3 LNU236 25424.2 0.118 0.690 10.6 LNU220 25405.1 0.806 0.468 16.9 LNU236 25423.3 0.116 0.436 8.8 LNU220 25405.5 0.756 0.004 9.6 LNU25 14082.8 0.119 0.185 12.4 LNU234 25014.6 0.763 0.443 10.5 LNU271 25911.4 0.124 0.033 16.5 LNU236 25425.4 0.838 0.373 21.4 LNU271 25913.3 0.109 0.633 2.9 LNU236 25424.2 0.781 0.546 13.3 LNU278 25814.1 0.111 0.707 4.7 LNU236 25423.3 0.731 0.508 6.0 LNU43 14423.6 0.118 0.062 11.2 LNU25 14082.8 0.900 0.066 30.5 LNU43 14423.7 0.111 0.511 4.1 LNU271 25911.4 0.738 0.065 6.9 LNU45 25052.12 0.123 0.467 15.3 LNU271 25913.2 0.725 0.360 5.1 LNU45 25053.4 0.121 0.004 14.1 LNU278 25814.1 0.738 0.507 6.9 LNU45 25052.11 0.118 0.341 10.6 LNU278 25814.3 0.719 0.334 4.2 LNU67 25821.5 0.150 0.379 41.2 LNU43 14423.6 0.775 0.007 12.4 LNU67 25823.5 0.126 0.010 18.2 LNU43 14422.9 0.731 0.197 6.0 LNU67 25824.3 0.118 0.045 10.6 LNU43 14423.7 0.700 0.767 1.5 LNU9 25001.2 0.122 0.205 14.7 LNU45 25052.12 0.813 0.431 17.8 LNU9 25003.1 0.118 0.341 10.6 LNU45 25053.4 0.813 0.139 17.8 LNU9 25001.3 0.110 0.710 3.5 LNU67 25821.5 0.994 0.378 44.1 CONT. — 0.110 — 0.0 LNU67 25821.4 0.831 0.000 20.5 LNU157 24982.8 0.130 0.146 18.6 LNU67 25823.5 0.775 0.099 12.4 LNU157 24982.4 0.123 0.285 11.8 LNU67 25824.3 0.763 0.014 10.5 LNU157 24983.3 0.120 0.318 9.5 LNU67 25824.5 0.738 0.507 6.9 LNU168 24754.2 0.116 0.617 5.5 LNU9 25003.1 0.819 0.238 18.7 LNU173 25451.5 0.164 0.027 49.4 LNU9 25001.7 0.725 0.510 5.1 LNU173 25451.11 0.155 0.001 41.4 LNU9 25001.2 0.706 0.562 2.4 LNU173 25451.1 0.140 0.140 27.8 CONT. — 0.728 — 0.0 LNU173 25451.2 0.139 0.337 27.2 LNU157 24982.8 0.856 0.199 17.7 LNU173 25451.12 0.131 0.235 19.2 LNU157 24982.4 0.794 0.422 9.1 LNU178 14612.1 0.126 0.575 14.6 LNU168 24754.2 0.856 0.199 17.7 LNU178 14611.5 0.122 0.233 11.2 LNU173 25451.5 1.069 0.001 46.9 LNU178 14611.4 0.121 0.239 10.6 LNU173 25451.11 1.019 0.002 40.0 LNU178 14611.1 0.120 0.419 9.5 LNU173 25451.2 0.950 0.073 30.5 LNU184 25393.3 0.163 0.236 48.3 LNU173 25451.1 0.938 0.047 28.8 LNU184 25393.1 0.148 0.007 34.6 LNU173 25451.12 0.888 0.399 21.9 LNU184 25393.2 0.147 0.109 34.0 LNU178 14611.4 0.913 0.019 25.4 LNU184 25395.1 0.132 0.075 20.3 LNU178 14612.1 0.869 0.525 19.4 LNU184 25394.3 0.121 0.239 10.6 LNU178 14611.5 0.850 0.092 16.8 LNU20 24933.4 0.154 0.034 40.9 LNU178 14611.1 0.800 0.286 9.9 LNU20 24932.4 0.143 0.431 30.0 LNU184 25393.1 0.994 0.013 36.5 LNU20 24934.1 0.142 0.019 29.5 LNU184 25393.3 0.994 0.100 36.5 LNU20 24933.1 0.120 0.617 9.5 LNU184 25393.2 0.975 0.027 34.0 LNU230 25413.2 0.162 0.022 47.7 LNU184 25395.1 0.888 0.103 21.9 LNU230 25413.1 0.144 0.005 31.7 LNU184 25394.3 0.856 0.077 17.7 LNU230 25415.1 0.144 0.007 31.2 LNU20 24933.4 1.088 0.002 49.4 LNU230 25412.2 0.126 0.148 15.2 LNU20 24934.1 0.950 0.010 30.5 LNU230 25412.1 0.119 0.510 8.4 LNU20 24932.4 0.851 0.585 16.9 LNU236 25425.4 0.153 0.002 39.2 LNU20 24933.1 0.825 0.280 13.4 LNU236 25424.2 0.124 0.160 12.9 LNU230 25413.2 1.131 0.000 55.4 LNU236 25422.4 0.119 0.502 8.9 LNU230 25413.1 0.969 0.043 33.1 LNU236 25423.3 0.119 0.343 8.4 LNU230 25415.1 0.925 0.014 27.1 LNU236 25425.3 0.116 0.546 5.5 LNU230 25412.2 0.913 0.024 25.4 LNU24 24971.3 0.158 0.001 44.3 LNU230 25412.1 0.800 0.315 9.9 LNU24 24971.2 0.143 0.029 30.6 LNU236 25425.4 1.031 0.001 41.7 LNU24 24971.4 0.136 0.141 24.3 LNU236 25422.4 0.863 0.271 18.5 LNU24 24974.2 0.123 0.205 11.8 LNU236 25424.2 0.850 0.092 16.8 LNU24 24972.1 0.116 0.533 5.5 LNU236 25423.3 0.831 0.141 14.2 LNU263 25794.8 0.156 0.050 42.0 LNU236 25425.3 0.800 0.315 9.9 LNU263 25794.6 0.146 0.047 33.5 LNU24 24971.3 0.994 0.003 36.5 LNU263 25794.3 0.141 0.162 28.9 LNU24 24971.2 0.963 0.104 32.3 LNU263 25791.3 0.138 0.021 26.0 LNU24 24971.4 0.869 0.282 19.4 LNU263 25792.2 0.129 0.524 18.1 LNU24 24974.2 0.863 0.067 18.5 LNU276 25433.2 0.144 0.006 31.2 LNU24 24972.1 0.831 0.141 14.2 LNU276 25433.1 0.133 0.362 20.9 LNU263 25794.8 0.988 0.004 35.7 LNU276 25433.3 0.131 0.045 19.8 LNU263 25794.6 0.938 0.011 28.8 LNU276 25433.5 0.124 0.685 12.9 LNU263 25794.3 0.913 0.164 25.4 LNU276 25431.1 0.117 0.611 6.7 LNU263 25792.2 0.900 0.186 23.7 LNU279 25481.5 0.165 0.000 50.6 LNU263 25791.3 0.888 0.043 21.9 LNU279 25481.3 0.163 0.000 48.3 LNU276 25433.2 0.944 0.100 29.7 LNU279 25481.4 0.146 0.022 32.9 LNU276 25433.1 0.881 0.139 21.1 LNU279 25481.2 0.144 0.237 31.7 LNU276 25433.3 0.838 0.230 15.1 LNU279 25484.3 0.132 0.137 20.3 LNU276 25433.5 0.831 0.601 14.2 LNU36 25561.2 0.188 0.000 71.1 LNU276 25431.1 0.819 0.231 12.5 LNU36 25562.3 0.183 0.214 66.5 LNU279 25481.5 1.063 0.001 46.0 LNU36 25562.7 0.131 0.057 19.2 LNU279 25481.2 0.981 0.228 34.8 LNU36 25562.9 0.123 0.367 11.8 LNU279 25484.3 0.981 0.016 34.8 LNU53 25674.1 0.136 0.022 23.8 LNU279 25481.4 0.975 0.056 34.0 LNU53 25674.3 0.119 0.502 8.9 LNU279 25481.3 0.931 0.333 28.0 LNU53 25674.6 0.118 0.383 7.8 LNU36 25562.3 1.325 0.249 82.1 LNU53 25674.2 0.114 0.659 3.8 LNU36 25561.2 1.175 0.000 61.5 LNU56 24693.1 0.164 0.042 49.4 LNU36 25562.9 0.938 0.013 28.8 LNU56 24691.2 0.151 0.006 37.5 LNU36 25562.7 0.913 0.019 25.4 LNU56 24693.2 0.137 0.187 24.9 LNU53 25674.1 0.906 0.058 24.5 LNU56 24694.2 0.133 0.032 21.5 LNU53 25674.6 0.831 0.178 14.2 LNU56 24694.1 0.133 0.186 20.9 LNU53 25674.3 0.819 0.545 12.5 LNU73 25755.1 0.142 0.008 29.5 LNU53 25674.2 0.781 0.423 7.3 LNU73 25751.9 0.138 0.129 25.5 LNU56 24693.1 1.125 0.000 54.6 LNU73 25751.1 0.133 0.063 21.5 LNU56 24693.2 0.988 0.023 35.7 LNU73 25751.8 0.118 0.628 7.2 LNU56 24691.2 0.938 0.010 28.8 LNU73 25754.2 0.116 0.488 6.1 LNU56 24694.1 0.938 0.047 28.8 LNU9 25001.7 0.163 0.236 48.3 LNU56 24694.2 0.925 0.014 27.1 LNU9 25001.1 0.137 0.020 24.9 LNU73 25751.9 0.963 0.007 32.3 LNU9 25001.3 0.119 0.314 8.9 LNU73 25755.1 0.894 0.225 22.8 LNU9 25001.2 0.116 0.655 6.1 LNU73 25751.1 0.881 0.041 21.1 CONT. — 0.112 — 0.0 LNU73 25751.8 0.806 0.557 10.8 LNU131 14005.5 0.150 0.000 34.2 LNU73 25754.2 0.763 0.650 4.8 LNU131 14002.15 0.138 0.186 23.0 LNU9 25001.7 1.031 0.213 41.7 LNU131 14005.2 0.133 0.015 18.5 LNU9 25001.1 0.981 0.004 34.8 LNU131 14002.12 0.119 0.302 6.8 LNU9 25001.3 0.863 0.079 18.5 LNU135 26204.2 0.156 0.103 39.2 LNU9 25001.2 0.794 0.343 9.1 LNU135 26203.4 0.137 0.363 22.4 CONT. — 0.865 — 0.0 LNU135 26203.6 0.128 0.021 14.6 LNU131 14002.15 0.981 0.019 13.4 LNU135 26203.1 0.125 0.074 11.8 LNU131 14005.5 0.931 0.259 7.6 LNU135 26204.4 0.118 0.315 5.1 LNU131 14005.2 0.925 0.193 6.9 LNU161 14552.7 0.124 0.673 10.7 LNU135 26204.2 1.063 0.003 22.8 LNU161 14553.4 0.123 0.207 9.6 LNU135 26203.4 0.956 0.542 10.5 LNU161 14553.6 0.122 0.343 9.0 LNU135 26203.6 0.950 0.202 9.8 LNU161 14552.9 0.121 0.457 7.9 LNU135 26203.1 0.906 0.471 4.7 LNU173 25451.5 0.119 0.455 6.2 LNU161 14552.9 0.956 0.220 10.5 LNU173 25451.11 0.115 0.753 2.9 LNU161 14552.7 0.925 0.690 6.9 LNU181 25771.6 0.116 0.522 3.4 LNU161 14553.4 0.881 0.722 1.9 LNU181 25771.2 0.115 0.516 2.9 LNU184 25395.1 1.031 0.181 19.2 LNU184 25395.1 0.153 0.000 36.4 LNU184 25393.3 0.975 0.054 12.7 LNU184 25394.3 0.134 0.104 20.2 LNU184 25394.1 0.931 0.561 7.6 LNU184 25394.1 0.131 0.039 16.9 LNU184 25394.3 0.913 0.594 5.5 LNU184 25393.3 0.127 0.007 13.5 LNU224 25874.4 1.063 0.166 22.8 LNU224 25874.4 0.141 0.250 26.4 LNU224 25872.2 1.013 0.051 17.0 LNU224 25871.3 0.136 0.001 21.9 LNU224 25871.3 0.956 0.220 10.5 LNU224 25872.2 0.136 0.068 21.9 LNU224 25872.3 0.904 0.500 4.5 LNU224 25872.3 0.133 0.063 19.0 LNU246 25744.2 1.044 0.312 20.6 LNU224 25874.1 0.132 0.076 18.0 LNU246 25743.1 0.963 0.049 11.2 LNU246 25744.2 0.140 0.232 25.2 LNU246 25743.2 0.963 0.082 11.2 LNU246 25743.1 0.135 0.211 20.8 LNU250 25592.1 1.000 0.135 15.6 LNU246 25743.2 0.131 0.143 16.9 LNU250 25592.2 0.963 0.049 11.2 LNU250 25592.2 0.149 0.195 33.1 LNU276 25433.5 1.163 0.004 34.4 LNU250 25592.1 0.132 0.008 18.0 LNU276 25433.6 0.931 0.704 7.6 LNU260 26404.8 0.126 0.021 12.9 LNU276 25433.3 0.919 0.353 6.2 LNU260 26404.7 0.125 0.585 11.8 LNU276 25433.1 0.894 0.670 3.3 LNU260 26403.1 0.121 0.239 7.9 LNU279 25481.2 1.106 0.146 27.9 LNU260 26403.2 0.115 0.566 2.9 LNU279 25481.3 1.100 0.038 27.1 LNU276 25433.5 0.146 0.113 30.3 LNU279 25481.4 1.094 0.023 26.4 LNU276 25433.6 0.133 0.212 19.1 LNU279 25484.3 1.088 0.000 25.7 LNU276 25433.1 0.122 0.407 9.0 LNU279 25481.5 1.025 0.095 18.5 LNU276 25433.3 0.119 0.164 6.8 LNU3 26124.1 1.106 0.146 27.9 LNU276 25431.1 0.113 0.800 1.2 LNU3 26122.2 1.100 0.082 27.1 LNU279 25481.3 0.151 0.320 35.3 LNU3 26123.6 0.994 0.011 14.9 LNU279 25484.3 0.149 0.000 33.6 LNU3 26123.5 0.894 0.791 3.3 LNU279 25481.4 0.148 0.120 31.9 LNU33 25553.2 1.010 0.103 16.7 LNU279 25481.2 0.134 0.104 20.2 LNU33 25552.2 0.906 0.404 4.7 LNU279 25481.5 0.129 0.268 15.7 CONT. — 0.723 — 0.0 LNU3 26122.2 0.147 0.000 31.4 LNU119 26142.8. 0.988 0.051 36.7 LNU3 26124.1 0.141 0.344 25.8 LNU119 26144.2. 0.913 0.000 26.3 LNU3 26123.6 0.126 0.230 12.4 LNU119 26142.5. 0.869 0.035 20.2 LNU3 26124.3 0.121 0.067 8.5 LNU119 26141.1. 0.819 0.563 13.3 LNU3 26123.5 0.121 0.459 8.5 LNU130 24912.7. 1.119 0.093 54.8 LNU33 25553.2 0.140 0.293 25.6 LNU130 24911.7. 1.113 0.000 54.0 LNU33 25552.2 0.138 0.161 23.6 LNU130 24913.5. 0.931 0.052 28.9 LNU33 25551.1 0.123 0.571 10.1 LNU130 24913.6. 0.913 0.000 26.3 CONT. — 0.072 — 0.0 LNU130 24914.5. 0.863 0.380 19.4 LNU119 26142.8. 0.094 0.155 30.0 LNU136 14511.10. 1.213 0.000 67.8 LNU119 26144.2. 0.088 0.179 21.3 LNU136 14514.8. 1.163 0.000 60.9 LNU119 26141.1. 0.081 0.474 12.7 LNU136 14515.5. 1.144 0.086 58.3 LNU130 24911.7. 0.118 0.000 63.8 LNU136 14513.6. 1.007 0.171 39.4 LNU130 24912.7. 0.114 0.189 58.6 LNU136 14515.1. 1.006 0.000 39.3 LNU130 24913.6. 0.098 0.003 36.0 LNU142 27541.1. 1.194 0.001 65.2 LNU130 24914.5. 0.094 0.405 30.8 LNU142 27545.1. 0.969 0.000 34.1 LNU130 24913.5. 0.091 0.129 26.5 LNU142 27546.1. 0.919 0.015 27.2 LNU136 14511.10. 0.131 0.018 82.0 LNU142 27546.2. 0.894 0.338 23.7 LNU136 14515.5. 0.124 0.014 72.4 LNU142 27541.2. 0.816 0.322 13.0 LNU136 14514.8. 0.114 0.000 58.6 LNU149 26175.3. 1.309 0.001 81.2 LNU136 14515.1. 0.102 0.000 41.2 LNU149 26175.1. 1.094 0.016 51.4 LNU136 14513.6. 0.099 0.068 37.2 LNU149 26175.7. 0.855 0.575 18.4 LNU142 27541.1. 0.126 0.003 74.2 LNU149 26174.4. 0.838 0.699 15.9 LNU142 27546.2. 0.101 0.007 40.4 LNU149 26174.6. 0.813 0.655 12.5 LNU142 27546.1. 0.095 0.188 31.7 LNU15 14123.11. 1.121 0.146 55.1 LNU142 27545.1. 0.094 0.056 30.0 LNU15 14123.13. 0.994 0.410 37.5 LNU142 27541.2. 0.080 0.450 10.3 LNU15 14122.8. 0.988 0.387 36.7 LNU149 26175.3. 0.135 0.098 86.9 LNU15 14122.9. 0.969 0.352 34.1 LNU149 26175.1. 0.116 0.002 61.2 LNU15 14124.12. 0.844 0.521 16.8 LNU149 26174.4. 0.094 0.352 30.8 LNU185 26475.1. 1.131 0.381 56.6 LNU149 26175.7. 0.093 0.203 28.6 LNU185 26474.1. 0.956 0.368 32.4 LNU149 26174.6. 0.081 0.651 12.7 LNU185 26473.1. 0.950 0.413 31.5 LNU15 14123.11. 0.118 0.012 63.2 LNU185 26474.2. 0.919 0.448 27.2 LNU15 14122.8. 0.103 0.403 43.0 LNU212 25834.4. 1.294 0.095 79.1 LNU15 14122.9. 0.103 0.401 42.1 LNU212 25834.5. 1.250 0.131 73.0 LNU15 14124.12. 0.092 0.246 27.4 LNU212 25834.1. 1.081 0.208 49.7 LNU15 14123.13. 0.091 0.183 26.5 LNU212 25833.2. 1.056 0.173 46.2 LNU185 26475.1. 0.120 0.272 66.4 LNU212 25832.1. 1.019 0.026 41.0 LNU185 26474.2. 0.108 0.374 49.9 LNU216 25985.4. 1.313 0.000 81.7 LNU185 26474.1. 0.094 0.429 30.8 LNU216 25982.1. 1.150 0.046 59.2 LNU185 26473.1. 0.093 0.297 28.2 LNU216 25984.6. 0.938 0.027 29.8 LNU212 25834.5. 0.134 0.024 86.3 LNU216 25982.2. 0.863 0.001 19.4 LNU212 25834.4. 0.126 0.092 74.2 LNU216 25984.1. 0.844 0.602 16.8 LNU212 25833.2. 0.121 0.082 67.2 LNU228 26222.4. 1.275 0.000 76.5 LNU212 25834.1. 0.116 0.118 60.3 LNU228 26222.1. 1.181 0.100 63.5 LNU212 25832.1. 0.103 0.006 42.1 LNU228 26224.7. 1.019 0.004 41.0 LNU216 25985.4. 0.119 0.097 64.6 LNU228 26225.2. 0.856 0.615 18.5 LNU216 25982.1. 0.109 0.103 50.8 LNU228 26224.6. 0.775 0.471 7.3 LNU216 25984.6. 0.084 0.015 16.1 LNU229 26112.3. 1.131 0.013 56.6 LNU216 25984.1. 0.083 0.586 14.4 LNU229 26111.5. 0.838 0.607 15.9 LNU216 25982.2. 0.076 0.437 4.9 LNU241 26232.4. 0.800 0.751 10.7 LNU228 26222.4. 0.133 0.000 83.7 LNU274 26261.3. 0.794 0.305 9.9 LNU228 26222.1. 0.115 0.215 59.4 LNU280 26164.4. 0.843 0.137 16.7 LNU228 26224.7. 0.100 0.215 38.6 LNU280 26162.1. 0.800 0.765 10.7 LNU228 26225.2. 0.091 0.511 26.5 LNU55 26013.9. 0.756 0.491 4.7 LNU228 26224.6. 0.086 0.448 18.7 LNU55 26015.1. 0.750 0.396 3.8 LNU229 26112.3. 0.113 0.117 56.0 LNU81 26034.2. 0.806 0.530 11.6 LNU229 26111.5. 0.086 0.658 19.6 CONT. — 0.625 — 0.0 LNU241 26232.4. 0.078 0.767 8.3 LNU119 26141.1. 0.769 0.001 23.0 LNU274 26261.3. 0.084 0.101 16.1 LNU119 26142.8. 0.719 0.318 15.0 LNU274 26263.2. 0.074 0.613 3.0 LNU119 26142.5. 0.688 0.554 10.0 LNU280 26162.1. 0.085 0.545 17.9 LNU119 26144.1. 0.681 0.053 9.0 LNU280 26164.4. 0.083 0.027 14.5 LNU119 26144.2. 0.650 0.708 4.0 LNU81 26034.2. 0.083 0.301 14.4 LNU130 24913.5. 0.856 0.067 37.0 LNU81 26034.3. 0.075 0.477 4.0 LNU130 24911.7. 0.794 0.446 27.0 CONT. — 0.084 — 0.0 LNU130 24912.7. 0.719 0.388 15.0 LNU119 26142.8. 0.097 0.259 15.4 LNU130 24913.6. 0.681 0.053 9.0 LNU119 26142.5. 0.093 0.583 10.2 LNU136 14514.8. 0.713 0.011 14.0 LNU119 26141.1. 0.092 0.136 9.4 LNU136 14515.1. 0.694 0.492 11.0 LNU130 24913.5. 0.104 0.006 23.6 LNU136 14515.5. 0.669 0.204 7.0 LNU130 24911.7. 0.094 0.675 11.7 LNU142 27546.1. 0.681 0.742 9.0 LNU130 24913.6. 0.094 0.448 11.7 LNU142 27545.1. 0.656 0.678 5.0 LNU130 24912.7. 0.092 0.680 9.4 LNU142 27546.2. 0.644 0.798 3.0 LNU149 26174.6. 0.102 0.307 21.4 LNU149 26174.6. 0.869 0.147 39.0 LNU149 26175.3. 0.096 0.416 14.6 LNU149 26175.3. 0.844 0.025 35.0 LNU149 26174.7. 0.089 0.592 5.7 LNU149 26174.7. 0.781 0.005 25.0 LNU15 14122.9. 0.093 0.441 10.2 LNU149 26174.8. 0.669 0.638 7.0 LNU15 14123.13. 0.087 0.788 3.5 LNU149 26175.1. 0.656 0.729 5.0 LNU185 26475.1. 0.093 0.213 10.2 LNU15 14122.9. 0.825 0.160 32.0 LNU212 25834.1. 0.128 0.278 51.9 LNU15 14122.8. 0.750 0.605 20.0 LNU212 25834.5. 0.119 0.326 42.2 LNU15 14123.11. 0.694 0.026 11.0 LNU212 25833.2. 0.106 0.326 25.8 LNU15 14123.13. 0.650 0.511 4.0 LNU212 25833.1. 0.101 0.381 20.6 LNU185 26475.1. 0.756 0.223 21.0 LNU212 25834.4. 0.096 0.410 13.9 LNU185 26474.1. 0.706 0.364 13.0 LNU216 25985.4. 0.131 0.110 56.3 LNU185 26474.2. 0.669 0.204 7.0 LNU216 25984.1. 0.123 0.002 45.9 LNU212 25834.1. 1.150 0.214 84.0 LNU216 25984.6. 0.109 0.336 30.3 LNU212 25834.5. 0.975 0.310 56.0 LNU216 25982.1. 0.102 0.218 21.3 LNU212 25833.2. 0.894 0.282 43.0 LNU216 25982.2. 0.097 0.037 15.4 LNU212 25834.4. 0.888 0.000 42.0 LNU228 26222.4. 0.138 0.102 64.5 LNU212 25833.1. 0.844 0.206 35.0 LNU228 26225.2. 0.138 0.000 63.8 LNU216 25985.4. 1.325 0.006 112.0 LNU228 26222.1. 0.136 0.067 61.5 LNU216 25984.1. 1.056 0.180 69.0 LNU228 26224.7. 0.133 0.000 57.9 LNU216 25984.6. 0.963 0.320 54.0 LNU228 26224.6. 0.132 0.097 57.1 LNU216 25982.2. 0.794 0.106 27.0 LNU229 26112.4. 0.139 0.032 65.3 LNU216 25982.1. 0.781 0.239 25.0 LNU229 26111.7. 0.136 0.017 62.3 LNU228 26224.7. 1.302 0.001 108.3 LNU229 26112.3. 0.123 0.058 45.9 LNU228 26222.4. 1.300 0.145 108.0 LNU229 26111.5. 0.121 0.007 43.7 LNU228 26224.6. 1.231 0.127 97.0 LNU241 26234.1. 0.119 0.069 41.4 LNU228 26222.1. 1.219 0.000 95.0 LNU241 26233.2. 0.104 0.114 23.6 LNU228 26225.2. 1.038 0.092 66.0 LNU241 26232.4. 0.103 0.007 22.8 LNU229 26111.7. 1.219 0.016 95.0 LNU241 26232.1. 0.099 0.080 18.4 LNU229 26111.5. 1.169 0.000 87.0 LNU241 26233.3. 0.094 0.322 11.7 LNU229 26112.4. 1.169 0.038 87.0 LNU253 26241.1. 0.129 0.000 54.1 LNU229 26112.3. 1.150 0.001 84.0 LNU253 26245.1. 0.125 0.000 48.9 LNU229 26114.1. 0.763 0.392 22.0 LNU253 26242.1. 0.124 0.110 47.4 LNU241 26234.1. 1.150 0.029 84.0 LNU253 26243.3. 0.105 0.004 25.1 LNU241 26232.4. 0.863 0.131 38.0 LNU253 26244.2. 0.103 0.329 22.8 LNU241 26233.3. 0.831 0.000 33.0 LNU274 26261.3. 0.126 0.575 50.4 LNU241 26232.1. 0.794 0.042 27.0 LNU274 26262.2. 0.126 0.050 50.4 LNU241 26233.2. 0.794 0.000 27.0 LNU274 26264.2. 0.121 0.000 43.7 LNU253 26245.1. 1.150 0.010 84.0 LNU274 26263.2. 0.116 0.033 37.7 LNU253 26242.1. 1.081 0.093 73.0 LNU274 26265.1. 0.111 0.063 32.5 LNU253 26241.1. 1.056 0.026 69.0 LNU277 25844.3. 0.116 0.412 37.7 LNU253 26243.3. 1.013 0.000 62.0 LNU277 25842.3. 0.115 0.001 37.0 LNU253 26244.2. 0.944 0.138 51.0 LNU277 25844.4. 0.105 0.102 25.1 LNU274 26263.2. 1.156 0.161 85.0 LNU277 25841.3. 0.097 0.497 15.4 LNU274 26262.2. 1.125 0.130 80.0 LNU277 25845.1. 0.091 0.696 8.3 LNU274 26261.3. 1.025 0.537 64.0 LNU280 26164.3. 0.131 0.132 56.3 LNU274 26264.2. 0.994 0.000 59.0 LNU280 26162.1. 0.126 0.227 49.6 LNU274 26265.1. 0.994 0.230 59.0 LNU280 26162.7. 0.111 0.493 32.1 LNU277 25842.3. 0.925 0.004 48.0 LNU280 26164.4. 0.098 0.223 17.0 LNU277 25844.3. 0.919 0.388 47.0 LNU280 26164.2. 0.098 0.332 16.1 LNU277 25841.3. 0.825 0.110 32.0 LNU55 26013.9. 0.099 0.467 17.6 LNU277 25844.4. 0.819 0.234 31.0 LNU81 26034.3. 0.098 0.141 16.1 LNU277 25845.1. 0.750 0.556 20.0 LNU280 26164.3. 1.119 0.189 79.0 LNU280 26162.1. 1.038 0.316 66.0 LNU280 26162.7. 0.953 0.360 52.4 LNU280 26164.4. 0.928 0.346 48.4 LNU280 26164.2. 0.800 0.356 28.0 LNU55 26013.9. 0.806 0.363 29.0 LNU55 26013.3. 0.731 0.565 17.0 LNU81 26034.3. 0.756 0.010 21.0 LNU81 26034.2. 0.681 0.053 9.0 Table 78. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

TABLE 79 Genes showing improved plant biomass production at limiting nitrogen growth conditions Rosette Rosette Area Plot Coverage Diameter [cm] [cm2] [%] Gene P- % Gene P- % Gene P- % Name Event # Ave. Value incr. Name Event # Ave. Value incr. Name Event # Ave. Value incr. CONT. — 3.606 — 0 CONT. — 4.630 — 0 CONT. — 36.6 — 0 LNU100 14472.2 4.256 0.154 18 LNU100 14472.2 6.287 0.060 36 LNU100 14472.2 50.3 0.050 37 LNU100 14471.4 4.115 0.102 14 LNU100 14471.4 5.556 0.016 20 LNU100 14471.4 44.5 0.012 21 LNU100 14474.3 3.819 0.148 6 LNU100 14473.3 4.782 0.448 3 LNU100 14473.3 38.3 0.339 5 LNU100 14473.3 3.744 0.244 4 LNU100 14474.3 4.748 0.505 3 LNU100 14474.3 38.0 0.375 4 LNU104 25033.3 4.546 0.000 26 LNU104 25033.3 6.633 0.000 43 LNU104 25033.3 53.1 0.000 45 LNU104 25032.2 4.232 0.000 17 LNU104 25032.2 6.169 0.166 33 LNU104 25032.2 49.4 0.154 35 LNU104 25032.1 4.113 0.187 14 LNU104 25032.1 5.559 0.115 20 LNU104 25032.1 44.5 0.097 22 LNU104 25033.1 3.852 0.005 7 LNU104 25033.1 5.070 0.158 10 LNU104 25033.1 40.6 0.126 11 LNU106 14481.1 4.267 0.237 18 LNU106 14481.1 6.059 0.128 31 LNU106 14481.1 48.5 0.115 32 LNU106 14483.5 4.070 0.260 13 LNU106 14483.5 5.508 0.264 19 LNU106 14483.5 44.1 0.243 20 LNU106 14484.3 3.952 0.004 10 LNU106 14483.2 5.269 0.017 14 LNU106 14483.2 42.2 0.013 15 LNU106 14483.2 3.927 0.059 9 LNU106 14484.3 5.251 0.041 13 LNU106 14484.3 42.0 0.031 15 LNU114 25042.1 3.824 0.009 6 LNU114 25041.2 5.048 0.584 9 LNU114 25041.2 40.4 0.544 10 LNU114 25041.2 3.809 0.559 6 LNU114 25042.1 5.030 0.127 9 LNU114 25042.1 37.8 0.797 3 LNU114 25041.1 3.764 0.650 4 LNU155 14525.1 5.470 0.145 18 LNU155 14525.1 43.8 0.125 20 LNU155 14525.1 3.907 0.281 8 LNU155 14523.5 5.131 0.517 11 LNU155 14523.5 41.1 0.480 12 LNU155 14523.5 3.768 0.668 4 LNU213 24654.4 5.291 0.068 14 LNU213 24654.4 42.3 0.053 16 LNU213 24652.4 3.789 0.690 5 LNU218 24781.7 5.948 0.000 28 LNU218 24781.7 47.6 0.000 30 LNU213 24654.4 3.787 0.032 5 LNU218 24781.4 5.916 0.220 28 LNU218 24781.4 47.3 0.206 29 LNU213 24653.2 3.731 0.735 3 LNU218 24784.2 5.573 0.127 20 LNU218 24784.2 44.6 0.109 22 LNU218 24781.7 4.252 0.031 18 LNU23 25163.5 5.631 0.533 22 LNU218 24781.2 37.5 0.666 3 LNU218 24781.4 4.196 0.104 16 LNU23 25163.6 5.104 0.623 10 LNU23 25163.5 45.1 0.515 23 LNU218 24784.2 3.967 0.003 10 LNU28 25171.2 5.541 0.000 20 LNU23 25163.6 40.8 0.589 12 LNU218 24781.2 3.729 0.137 3 LNU28 25171.1 5.522 0.000 19 LNU28 25171.2 44.3 0.000 21 LNU23 25163.5 4.157 0.442 15 LNU4 25133.3 5.633 0.001 22 LNU28 25171.1 44.2 0.001 21 LNU23 25163.6 3.923 0.471 9 LNU4 25134.1 4.919 0.614 6 LNU4 25133.3 45.1 0.001 23 LNU23 25162.1 3.663 0.407 2 LNU40 24794.3 5.925 0.016 28 LNU4 25134.1 39.4 0.557 8 LNU28 25171.1 4.244 0.001 18 LNU40 24794.4 5.510 0.201 19 LNU40 24794.3 47.4 0.012 30 LNU28 25171.2 4.046 0.000 12 LNU46 14462.5 7.136 0.169 54 LNU40 24794.4 41.5 0.529 13 LNU28 25174.5 3.751 0.795 4 LNU46 14464.4 6.666 0.333 44 LNU46 14462.5 57.1 0.163 56 LNU4 25133.3 4.119 0.000 14 LNU46 14463.1 5.094 0.053 10 LNU46 14464.4 53.3 0.325 46 LNU4 25134.1 3.793 0.427 5 LNU46 14464.1 5.091 0.285 10 LNU46 14463.1 40.8 0.042 11 LNU4 25131.1 3.711 0.305 3 LNU46 14462.1 4.978 0.516 8 LNU46 14464.1 40.7 0.244 11 LNU40 24794.3 4.091 0.000 13 LNU48 24801.4 6.013 0.000 30 LNU46 14462.1 39.8 0.463 9 LNU40 24794.4 4.033 0.018 12 LNU48 24802.1 5.221 0.008 13 LNU48 24801.4 48.1 0.000 31 LNU46 14462.5 4.468 0.163 24 LNU48 24804.4 4.891 0.171 6 LNU48 24802.1 41.8 0.007 14 LNU46 14464.4 4.460 0.263 24 LNU63 24814.2 5.537 0.003 20 LNU48 24804.4 39.1 0.131 7 LNU46 14464.1 3.912 0.179 8 LNU63 24814.3 5.022 0.132 8 LNU63 24814.2 44.3 0.002 21 LNU46 14463.1 3.806 0.215 6 LNU63 24811.2 4.848 0.409 5 LNU63 24814.3 40.2 0.102 10 LNU46 14462.1 3.803 0.317 5 LNU7 25081.1 5.350 0.006 16 LNU63 24811.2 38.8 0.326 6 LNU48 24801.4 4.262 0.000 18 LNU7 25082.2 5.052 0.320 9 LNU7 25081.1 42.8 0.005 17 LNU48 24802.1 3.989 0.000 11 LNU8 25062.1 5.062 0.031 9 LNU7 25082.2 40.4 0.275 10 LNU48 24804.4 3.707 0.232 3 LNU8 25063.6 5.017 0.229 8 LNU8 25062.1 40.5 0.027 11 LNU63 24814.2 4.060 0.000 13 LNU8 25062.2 4.960 0.219 7 LNU8 25063.6 40.1 0.185 10 LNU63 24814.3 3.864 0.004 7 LNU8 25061.2 4.837 0.300 4 LNU8 25062.2 39.7 0.172 8 LNU63 24811.2 3.717 0.286 3 LNU94 24833.3 5.355 0.037 16 LNU8 25061.2 38.7 0.226 6 LNU7 25081.1 3.996 0.002 11 LNU96 25071.2 5.810 0.305 25 LNU94 24833.3 40.1 0.178 10 LNU7 25082.2 3.864 0.348 7 LNU96 25073.4 4.985 0.729 8 LNU96 25071.2 46.5 0.290 27 LNU8 25063.6 3.835 0.028 6 LNU96 25071.3 4.854 0.524 5 LNU96 25073.4 39.9 0.693 9 LNU8 25061.2 3.731 0.387 3 CONT. — 5.751 — 0 CONT. — 46.0 — 0 LNU8 25062.2 3.731 0.092 3 LNU113 25631.7 6.330 0.502 10 LNU113 25631.7 50.6 0.502 10 LNU8 25062.1 3.659 0.573 1 LNU113 25631.3 6.104 0.634 6 LNU113 25631.3 48.8 0.634 6 LNU94 24833.3 3.913 0.030 9 LNU113 25631.1 5.964 0.236 4 LNU113 25631.1 47.7 0.236 4 LNU96 25071.2 4.171 0.281 16 LNU120 25463.6 5.862 0.757 2 LNU120 25463.6 46.9 0.757 2 LNU96 25073.4 3.883 0.603 8 LNU140 14115.1 6.053 0.639 5 LNU140 14115.1 48.4 0.639 5 LNU96 25071.3 3.827 0.491 6 LNU148 25685.6 7.625 0.100 33 LNU148 25685.6 61.0 0.100 33 CONT. — 3.931 — 0 LNU148 25685.1 6.612 0.066 15 LNU148 25685.1 52.9 0.066 15 LNU113 25631.3 4.273 0.384 9 LNU148 25685.9 6.006 0.756 4 LNU148 25685.9 48.1 0.756 4 LNU113 25631.7 4.196 0.311 7 LNU287 24674.6 5.818 0.717 1 LNU287 24674.6 46.5 0.717 1 LNU113 25631.1 4.081 0.064 4 LNU5 14043.7 6.452 0.317 12 LNU5 14043.7 51.6 0.317 12 LNU120 25463.3 4.027 0.218 2 LNU68 14035.5 5.933 0.381 3 LNU68 14035.5 47.5 0.381 3 LNU124 14501.1 4.008 0.346 2 LNU74 25444.1 6.292 0.127 9 LNU74 25444.1 50.3 0.127 9 LNU132 14102.6 4.040 0.554 3 LNU74 25443.2 5.820 0.674 1 LNU74 25443.2 46.6 0.674 1 LNU140 14115.1 4.026 0.704 2 LNU98 25763.2 5.892 0.745 2 LNU98 25763.2 47.1 0.745 2 LNU148 25685.6 4.481 0.166 14 CONT. — 5.257 — 0 CONT. — 41.6 — 0 LNU148 25685.1 4.295 0.056 9 LNU113 25631.9 5.826 0.342 11 LNU113 25631.9 46.6 0.302 12 LNU287 24674.6 4.081 0.322 4 LNU148 25685.1 5.876 0.263 12 LNU148 25685.1 47.0 0.228 13 LNU5 14043.7 4.199 0.258 7 LNU72 24963.7 5.957 0.447 13 LNU72 24963.7 47.7 0.417 15 LNU68 14035.5 4.069 0.056 4 LNU72 24962.3 5.592 0.691 6 LNU72 24962.3 44.7 0.643 8 LNU74 25444.1 4.110 0.149 5 LNU98 25763.2 5.771 0.476 10 LNU98 25763.2 46.2 0.434 11 LNU74 25443.2 3.977 0.479 1 CONT. — 4.937 — 0 CONT. — 38.1 — 0 LNU98 25763.2 4.019 0.561 2 LNU117 25931.4 8.201 0.038 66 LNU117 25931.4 65.6 0.031 72 CONT. — 3.861 — 0 LNU117 25931.2 7.079 0.047 43 LNU117 25931.2 56.6 0.055 49 LNU113 25631.9 4.102 0.390 6 LNU117 25933.3 6.946 0.038 41 LNU117 25933.3 55.6 0.058 46 LNU113 25631.3 3.943 0.755 2 LNU117 25931.1 6.455 0.297 31 LNU117 25931.1 51.6 0.257 35 LNU148 25685.1 4.083 0.380 6 LNU117 25932.4 6.152 0.430 25 LNU117 25932.4 49.2 0.381 29 LNU72 24963.7 4.114 0.536 7 LNU122 25333.2 7.762 0.015 57 LNU122 25333.2 62.1 0.029 63 LNU98 25763.2 4.030 0.446 4 LNU122 25332.1 7.548 0.257 53 LNU122 25332.1 60.4 0.226 58 CONT. — 3.681 — 0 LNU122 25332.2 6.704 0.053 36 LNU122 25332.2 53.6 0.083 41 LNU117 25931.4 4.672 0.079 27 LNU122 25332.5 6.165 0.112 25 LNU122 25332.5 49.3 0.145 29 LNU117 25933.3 4.364 0.041 19 LNU122 25333.1 6.130 0.142 24 LNU122 25333.1 49.0 0.160 29 LNU117 25931.2 4.320 0.047 17 LNU125 25941.4 8.098 0.097 64 LNU125 25941.4 64.8 0.074 70 LNU117 25932.4 4.197 0.333 14 LNU125 25943.3 7.176 0.030 45 LNU125 25943.3 57.4 0.053 51 LNU117 25931.1 4.189 0.192 14 LNU125 25943.2 6.828 0.370 38 LNU125 25943.2 54.6 0.334 43 LNU122 25332.1 4.536 0.164 23 LNU125 25941.2 6.448 0.309 31 LNU125 25941.2 51.6 0.268 35 LNU122 25333.2 4.522 0.024 23 LNU125 25944.3 6.167 0.380 25 LNU125 25944.3 49.3 0.333 29 LNU122 25332.2 4.252 0.076 16 LNU138 14074.5 7.777 0.014 58 LNU138 14074.5 62.2 0.029 63 LNU122 25333.1 4.135 0.102 12 LNU138 14074.6 7.468 0.181 51 LNU138 14074.6 59.7 0.149 57 LNU122 25332.5 4.098 0.228 11 LNU138 14071.5 6.727 0.051 36 LNU138 14071.5 53.8 0.074 41 LNU125 25941.4 4.714 0.088 28 LNU138 14072.8 5.184 0.664 5 LNU138 14072.8 41.5 0.580 9 LNU125 25943.3 4.442 0.039 21 LNU180 24721.2 9.058 0.043 83 LNU138 14072.5 40.1 0.740 5 LNU125 25943.2 4.326 0.317 18 LNU180 24723.1 8.587 0.010 74 LNU180 24721.2 72.5 0.030 90 LNU125 25941.2 4.212 0.315 14 LNU180 24721.4 8.409 0.017 70 LNU180 24723.1 68.7 0.014 80 LNU125 25944.3 4.191 0.197 14 LNU180 24722.2 7.901 0.179 60 LNU180 24721.4 67.3 0.018 76 LNU138 14074.5 4.654 0.016 26 LNU180 24724.1 7.457 0.117 51 LNU180 24722.2 63.2 0.150 66 LNU138 14074.6 4.553 0.132 24 LNU220 25405.2 7.726 0.048 56 LNU180 24724.1 59.7 0.093 56 LNU138 14071.5 4.284 0.060 16 LNU220 25405.5 7.662 0.086 55 LNU220 25405.2 61.8 0.041 62 LNU138 14072.5 3.780 0.639 3 LNU220 25405.1 7.524 0.216 52 LNU220 25405.5 61.3 0.068 61 LNU138 14072.8 3.760 0.685 2 LNU220 25405.6 6.268 0.091 27 LNU220 25405.1 60.2 0.184 58 LNU180 24721.2 5.125 0.010 39 LNU220 25405.3 5.915 0.406 20 LNU220 25405.6 50.1 0.130 32 LNU180 24723.1 4.878 0.018 33 LNU230 25413.1 8.332 0.014 69 LNU220 25405.3 47.3 0.356 24 LNU180 24721.4 4.870 0.010 32 LNU230 25412.1 7.791 0.079 58 LNU230 25413.1 66.7 0.018 75 LNU180 24722.2 4.783 0.121 30 LNU230 25415.1 7.230 0.167 46 LNU230 25412.1 62.3 0.061 63 LNU180 24724.1 4.538 0.062 23 LNU230 25412.2 6.904 0.045 40 LNU230 25415.1 57.8 0.137 52 LNU220 25405.5 4.611 0.090 25 LNU230 25413.2 6.826 0.274 38 LNU230 25413.2 54.6 0.236 43 LNU220 25405.1 4.497 0.217 22 LNU234 25014.8 7.333 0.034 49 LNU230 25412.2 51.7 0.100 36 LNU220 25405.2 4.485 0.035 22 LNU234 25014.1 6.560 0.125 33 LNU234 25014.8 58.7 0.053 54 LNU220 25405.6 4.220 0.089 15 LNU234 25014.6 6.438 0.079 30 LNU234 25014.1 52.5 0.119 38 LNU220 25405.3 4.043 0.244 10 LNU234 25014.4 6.183 0.121 25 LNU234 25014.6 51.5 0.113 35 LNU230 25413.1 4.814 0.021 31 LNU234 25014.5 5.958 0.451 21 LNU234 25014.4 49.5 0.146 30 LNU230 25412.1 4.738 0.044 29 LNU25 14082.8 7.851 0.067 59 LNU234 25014.5 47.7 0.398 25 LNU230 25415.1 4.453 0.193 21 LNU25 14083.7 7.683 0.025 56 LNU25 14082.8 62.8 0.052 65 LNU230 25412.2 4.390 0.049 19 LNU25 14082.9 7.494 0.021 52 LNU25 14083.7 61.5 0.041 61 LNU230 25413.2 4.226 0.340 15 LNU25 14084.6 7.440 0.229 51 LNU25 14082.9 59.9 0.040 57 LNU234 25014.8 4.643 0.017 26 LNU25 14083.1 7.369 0.024 49 LNU25 14084.6 59.5 0.196 56 LNU234 25014.1 4.390 0.202 19 LNU254 25782.4 8.004 0.020 62 LNU25 14083.1 58.9 0.044 55 LNU234 25014.6 4.206 0.086 14 LNU254 25781.3 7.690 0.025 56 LNU254 25782.4 64.0 0.034 68 LNU234 25014.5 4.196 0.250 14 LNU254 25781.5 7.136 0.064 45 LNU254 25781.3 61.5 0.031 61 LNU234 25014.4 4.160 0.121 13 LNU254 25782.5 6.589 0.062 33 LNU254 25781.5 57.1 0.062 50 LNU25 14082.8 4.776 0.101 30 LNU254 25783.1 6.556 0.250 33 LNU254 25782.5 52.7 0.086 38 LNU25 14082.9 4.731 0.018 29 LNU263 25794.8 7.806 0.182 58 LNU254 25783.1 52.5 0.214 38 LNU25 14083.1 4.630 0.018 26 LNU263 25794.3 7.786 0.015 58 LNU263 25794.8 62.4 0.152 64 LNU25 14083.7 4.596 0.033 25 LNU263 25791.3 7.761 0.041 57 LNU263 25794.3 62.3 0.027 63 LNU25 14084.6 4.556 0.263 24 LNU263 25794.6 7.305 0.024 48 LNU263 25791.3 62.1 0.037 63 LNU254 25782.4 4.741 0.020 29 LNU263 25792.2 7.079 0.031 43 LNU263 25794.6 58.4 0.045 53 LNU254 25781.3 4.696 0.046 28 LNU267 25804.4 7.228 0.038 46 LNU263 25792.2 56.6 0.051 49 LNU254 25781.5 4.485 0.027 22 LNU267 25804.3 7.196 0.098 46 LNU267 25804.4 57.8 0.058 52 LNU254 25782.5 4.354 0.060 18 LNU267 25801.1 6.656 0.227 35 LNU267 25804.3 57.6 0.082 51 LNU254 25783.1 4.174 0.325 13 LNU267 25803.1 6.585 0.059 33 LNU267 25801.1 53.2 0.193 40 LNU263 25794.8 4.696 0.165 28 LNU267 25802.1 6.188 0.147 25 LNU267 25803.1 52.7 0.092 38 LNU263 25794.3 4.651 0.022 26 LNU271 25911.4 8.631 0.011 75 LNU267 25802.1 49.5 0.156 30 LNU263 25791.3 4.640 0.023 26 LNU271 25912.1 7.598 0.052 54 LNU271 25911.4 69.1 0.021 81 LNU263 25794.6 4.565 0.022 24 LNU271 25913.3 6.587 0.069 33 LNU271 25912.1 57.3 0.192 50 LNU263 25792.2 4.422 0.034 20 LNU271 25912.2 6.006 0.141 22 LNU271 25913.3 52.7 0.089 38 LNU267 25804.3 4.532 0.064 23 LNU271 25913.2 5.306 0.743 7 LNU271 25912.2 48.1 0.181 26 LNU267 25804.4 4.525 0.032 23 LNU278 25814.3 8.097 0.011 64 LNU271 25913.2 42.4 0.653 11 LNU267 25803.1 4.381 0.052 19 LNU278 25812.3 8.034 0.021 63 LNU278 25814.3 64.8 0.022 70 LNU267 25801.1 4.216 0.143 15 LNU278 25812.2 6.641 0.088 35 LNU278 25812.3 64.3 0.034 69 LNU267 25802.1 4.181 0.156 14 LNU278 25814.1 6.351 0.218 29 LNU278 25812.2 53.1 0.094 39 LNU271 25911.4 5.046 0.006 37 LNU278 25813.2 5.577 0.364 13 LNU278 25814.1 50.8 0.191 33 LNU271 25912.1 4.508 0.033 22 LNU36 25562.9 7.926 0.019 61 LNU278 25813.2 44.6 0.349 17 LNU271 25913.3 4.382 0.064 19 LNU36 25562.3 6.823 0.049 38 LNU36 25562.9 63.4 0.033 66 LNU271 25912.2 4.152 0.102 13 LNU36 25562.4 6.281 0.088 27 LNU36 25562.3 54.6 0.076 43 LNU271 25913.2 3.894 0.579 6 LNU36 25562.7 5.943 0.154 20 LNU36 25562.4 50.3 0.125 32 LNU278 25812.3 4.752 0.020 29 LNU36 25561.2 5.749 0.222 16 LNU36 25562.7 47.5 0.194 25 LNU278 25814.3 4.655 0.028 26 LNU43 14422.8 7.369 0.026 49 LNU36 25561.2 46.0 0.256 21 LNU278 25812.2 4.267 0.059 16 LNU43 14422.9 6.842 0.040 39 LNU43 14422.8 59.0 0.046 55 LNU278 25814.1 4.121 0.113 12 LNU43 14421.1 6.814 0.042 38 LNU43 14422.9 54.7 0.065 44 LNU278 25813.2 3.927 0.294 7 LNU43 14423.6 6.361 0.080 29 LNU43 14421.1 54.5 0.068 43 LNU36 25562.9 4.633 0.027 26 LNU43 14423.7 6.061 0.312 23 LNU43 14423.6 50.9 0.113 33 LNU36 25562.3 4.246 0.070 15 LNU45 25052.12 7.449 0.059 51 LNU43 14423.7 48.5 0.275 27 LNU36 25561.2 4.090 0.137 11 LNU45 25052.8 7.250 0.025 47 LNU45 25052.12 59.6 0.052 56 LNU36 25562.7 4.023 0.177 9 LNU45 25052.9 6.722 0.055 36 LNU45 25052.8 58.0 0.045 52 LNU36 25562.4 4.008 0.221 9 LNU45 25053.4 6.464 0.464 31 LNU45 25052.9 53.8 0.075 41 LNU43 14422.8 4.553 0.028 24 LNU45 25052.11 5.637 0.269 14 LNU45 25053.4 51.7 0.424 36 LNU43 14421.1 4.514 0.032 23 LNU67 25821.5 6.477 0.348 31 LNU45 25052.11 45.1 0.297 18 LNU43 14422.9 4.354 0.042 18 LNU67 25824.5 6.258 0.293 27 LNU67 25821.5 51.8 0.306 36 LNU43 14423.6 4.283 0.088 16 LNU67 25823.5 6.011 0.155 22 LNU67 25824.5 50.1 0.255 31 LNU43 14423.7 4.074 0.318 11 LNU67 25821.4 5.761 0.238 17 LNU67 25823.5 48.1 0.181 26 LNU45 25052.12 4.543 0.106 23 LNU67 25824.3 5.603 0.597 13 LNU67 25821.4 46.1 0.257 21 LNU45 25052.8 4.344 0.057 18 CONT. — 3.923 — 0 LNU67 25824.3 44.8 0.528 18 LNU45 25052.9 4.226 0.108 15 LNU100 14474.2 5.788 0.078 48 CONT. — 31.4 — 0 LNU45 25053.4 4.169 0.483 13 LNU100 14472.1 5.604 0.332 43 LNU100 14474.2 46.3 0.078 48 LNU45 25052.11 3.898 0.323 6 LNU100 14473.3 5.227 0.373 33 LNU100 14472.1 44.8 0.332 43 LNU67 25821.5 4.189 0.385 14 LNU100 14473.1 5.199 0.202 33 LNU100 14473.3 41.8 0.373 33 LNU67 25824.5 4.160 0.342 13 LNU100 14471.4 4.583 0.510 17 LNU100 14473.1 41.6 0.202 33 LNU67 25823.5 4.049 0.152 10 LNU104 25032.2 4.811 0.483 23 LNU100 14471.4 36.7 0.510 17 LNU67 25824.3 4.010 0.423 9 LNU104 25033.1 4.727 0.319 21 LNU104 25032.2 38.5 0.483 23 LNU67 25821.4 3.971 0.295 8 LNU104 25032.1 4.607 0.401 17 LNU104 25033.1 37.8 0.319 21 CONT. — 3.345 — 0 LNU104 25033.3 4.515 0.021 15 LNU104 25032.1 36.9 0.401 17 LNU100 14474.2 4.215 0.024 26 LNU106 14483.2 5.906 0.009 51 LNU104 25033.3 36.1 0.021 15 LNU100 14472.1 4.080 0.377 22 LNU106 14481.1 5.002 0.460 28 LNU106 14483.2 47.3 0.009 51 LNU100 14473.3 3.988 0.272 19 LNU106 14483.5 4.726 0.003 20 LNU106 14481.1 40.0 0.460 28 LNU100 14473.1 3.860 0.145 15 LNU106 14484.3 4.471 0.599 14 LNU106 14483.5 37.8 0.003 20 LNU100 14471.4 3.657 0.440 9 LNU114 25044.11 5.196 0.404 32 LNU106 14484.3 35.8 0.599 14 LNU104 25033.1 3.784 0.440 13 LNU114 25041.2 5.087 0.105 30 LNU114 25044.11 41.6 0.404 32 LNU104 25033.3 3.769 0.127 13 LNU114 25042.1 4.666 0.316 19 LNU114 25041.2 40.7 0.105 30 LNU104 25032.1 3.733 0.185 12 LNU114 25041.1 4.424 0.790 13 LNU114 25042.1 37.3 0.316 19 LNU104 25032.2 3.695 0.465 10 LNU114 25044.4 4.267 0.800 9 LNU114 25041.1 35.4 0.790 13 LNU106 14483.2 4.299 0.001 29 LNU114 25932.4 5.264 0.026 34 LNU114 25044.4 34.1 0.800 9 LNU106 14481.1 3.952 0.369 18 LNU117 25931.4 5.003 0.007 28 LNU117 25932.4 42.1 0.026 34 LNU106 14483.5 3.741 0.029 12 LNU117 25931.1 4.406 0.731 12 LNU117 25931.4 40.0 0.007 28 LNU106 14484.3 3.573 0.544 7 LNU117 25931.2 4.256 0.596 9 LNU117 25931.1 35.2 0.731 12 LNU114 25044.11 3.992 0.266 19 LNU155 14523.5 5.064 0.371 29 LNU117 25931.2 34.1 0.596 9 LNU114 25041.2 3.908 0.005 17 LNU155 14524.8 4.210 0.411 7 LNU155 14523.5 40.5 0.371 29 LNU114 25042.1 3.783 0.193 13 LNU180 24723.1 4.999 0.001 27 LNU155 14524.8 33.7 0.411 7 LNU114 25041.1 3.667 0.691 10 LNU180 24722.2 4.503 0.696 15 LNU180 24723.1 40.0 0.001 27 LNU117 25932.4 4.072 0.091 22 LNU218 24781.4 5.394 0.065 38 LNU180 24722.2 36.0 0.696 15 LNU117 25931.4 3.797 0.001 14 LNU218 24781.1 4.950 0.283 26 LNU218 24781.4 43.2 0.065 38 LNU117 25931.1 3.637 0.607 9 LNU218 24781.6 4.116 0.510 5 LNU218 24781.1 39.6 0.283 26 LNU117 25931.2 3.493 0.531 4 LNU218 24781.2 4.052 0.541 3 LNU218 24781.6 32.9 0.510 5 LNU155 14523.5 3.825 0.342 14 LNU254 25782.5 4.883 0.061 24 LNU218 24781.2 32.4 0.541 3 LNU155 14524.8 3.615 0.063 8 LNU4 25134.3 5.451 0.299 39 LNU254 25782.5 39.1 0.061 24 LNU180 24723.1 3.874 0.067 16 LNU4 25134.2 4.702 0.210 20 LNU4 25134.3 43.6 0.299 39 LNU180 24722.2 3.708 0.619 11 LNU4 25131.1 4.628 0.422 18 LNU4 25134.2 37.6 0.210 20 LNU218 24781.4 4.130 0.080 23 LNU4 25133.3 4.261 0.501 9 LNU4 25131.1 37.0 0.422 18 LNU218 24781.1 4.061 0.057 21 LNU40 24794.3 4.596 0.661 17 LNU4 25133.3 34.1 0.501 9 LNU218 24781.2 3.582 0.031 7 LNU40 24792.1 4.508 0.017 15 LNU40 24794.3 36.8 0.661 17 LNU218 24781.6 3.522 0.244 5 LNU40 24794.4 4.144 0.345 6 LNU40 24792.1 36.1 0.017 15 LNU254 25782.5 3.825 0.120 14 LNU46 14462.5 5.330 0.315 36 LNU40 24794.4 33.2 0.345 6 LNU254 25782.4 3.387 0.697 1 LNU46 14464.4 4.290 0.256 9 LNU46 14462.5 42.6 0.315 36 LNU4 25134.3 4.057 0.310 21 LNU46 14462.1 4.285 0.114 9 LNU46 14464.4 34.3 0.256 9 LNU4 25134.2 3.667 0.282 10 LNU48 24801.4 4.780 0.139 22 LNU46 14462.1 34.3 0.114 9 LNU4 25131.1 3.643 0.535 9 LNU48 24803.2 4.595 0.596 17 LNU48 24801.4 38.2 0.139 22 LNU4 25133.3 3.533 0.527 6 LNU63 24812.3 5.325 0.111 36 LNU48 24803.2 36.8 0.596 17 LNU40 24794.3 3.803 0.557 14 LNU63 24814.7 4.440 0.426 13 LNU63 24812.3 42.6 0.111 36 LNU40 24792.1 3.682 0.005 10 LNU7 25082.2 4.973 0.460 27 LNU63 24814.7 35.5 0.426 13 LNU40 24794.4 3.484 0.177 4 LNU7 25083.1 4.472 0.220 14 LNU7 25082.2 39.8 0.460 27 LNU46 14462.5 3.977 0.353 19 LNU7 25083.3 4.378 0.198 12 LNU7 25083.1 35.8 0.220 14 LNU46 14462.1 3.575 0.041 7 LNU8 25063.6 5.383 0.119 37 LNU7 25083.3 35.0 0.198 12 LNU46 14464.4 3.512 0.213 5 LNU8 25061.2 4.703 0.003 20 LNU8 25063.6 43.1 0.119 37 LNU48 24803.2 3.731 0.520 12 LNU94 24833.3 4.639 0.511 18 LNU8 25061.2 37.6 0.003 20 LNU48 24801.4 3.724 0.156 11 CONT. — 5.138 — 0 LNU94 24833.3 37.1 0.511 18 LNU48 24802.2 3.457 0.760 3 LNU122 25332.1 6.084 0.057 18 CONT. — 41.1 — 0 LNU63 24812.3 4.044 0.067 21 LNU122 25332.2 6.037 0.049 18 LNU122 25332.1 48.7 0.057 18 LNU63 24814.7 3.580 0.458 7 LNU122 25332.5 5.627 0.601 10 LNU122 25332.2 48.3 0.049 18 LNU63 24814.2 3.498 0.361 5 LNU125 25943.2 5.541 0.155 8 LNU122 25332.5 45.0 0.601 10 LNU7 25082.2 3.789 0.443 13 LNU125 25941.4 5.481 0.153 7 LNU125 25943.2 44.3 0.155 8 LNU7 25083.1 3.697 0.020 11 LNU138 14074.5 5.527 0.128 8 LNU125 25941.4 43.8 0.153 7 LNU7 25083.3 3.566 0.325 7 LNU138 14071.5 5.204 0.795 1 LNU138 14074.5 44.2 0.128 8 LNU8 25063.6 4.011 0.034 20 LNU157 24982.1 5.356 0.680 4 LNU138 14071.5 41.6 0.795 1 LNU8 25061.2 3.745 0.002 12 LNU178 14614.5 5.971 0.096 16 LNU157 24982.1 42.8 0.680 4 LNU94 24833.3 3.572 0.610 7 LNU178 14611.5 5.656 0.022 10 LNU178 14614.5 47.8 0.096 16 CONT. — 3.921 — 0 LNU178 14612.1 5.477 0.551 7 LNU178 14611.5 45.3 0.022 10 LNU10 25123.5 4.081 0.621 4 LNU178 14611.4 5.445 0.126 6 LNU178 14612.1 43.8 0.551 7 LNU122 25332.1 4.326 0.175 10 LNU220 25405.6 5.656 0.282 10 LNU178 14611.4 43.6 0.126 6 LNU122 25332.2 4.305 0.000 10 LNU220 25405.1 5.643 0.024 10 LNU220 25405.6 45.2 0.282 10 LNU122 25332.5 4.214 0.324 7 LNU220 25405.5 5.597 0.084 9 LNU220 25405.1 45.1 0.024 10 LNU122 25333.2 3.972 0.796 1 LNU220 25405.2 5.420 0.567 5 LNU220 25405.5 44.8 0.084 9 LNU125 25941.4 4.108 0.072 5 LNU234 25014.6 5.343 0.764 4 LNU220 25405.2 43.4 0.567 5 LNU125 25943.2 4.065 0.372 4 LNU236 25424.2 6.609 0.163 29 LNU234 25014.6 42.7 0.764 4 LNU138 14074.5 4.227 0.004 8 LNU236 25422.4 5.751 0.104 12 LNU236 25424.2 52.9 0.163 29 LNU138 14071.5 4.055 0.110 3 LNU236 25425.4 5.715 0.461 11 LNU236 25422.4 46.0 0.104 12 LNU138 14074.6 3.995 0.626 2 LNU236 25423.3 5.617 0.562 9 LNU236 25425.4 45.7 0.461 11 LNU157 24982.1 4.149 0.283 6 LNU24 24974.2 5.406 0.476 5 LNU236 25423.3 44.9 0.562 9 LNU178 14614.5 4.306 0.077 10 LNU25 14082.8 6.389 0.000 24 LNU24 24974.2 43.2 0.476 5 LNU178 14611.5 4.250 0.119 8 LNU25 14082.9 5.548 0.099 8 LNU25 14082.8 51.1 0.000 24 LNU178 14611.4 4.135 0.015 5 LNU25 14084.6 5.424 0.348 6 LNU25 14082.9 44.4 0.099 8 LNU178 14612.1 4.004 0.628 2 LNU271 25911.4 5.716 0.647 11 LNU25 14084.6 43.4 0.348 6 LNU220 25405.6 4.098 0.215 5 LNU278 25814.1 5.701 0.013 11 LNU271 25911.4 45.7 0.647 11 LNU220 25405.5 4.062 0.115 4 LNU278 25814.3 5.444 0.283 6 LNU278 25814.1 45.6 0.013 11 LNU220 25405.1 4.012 0.543 2 LNU278 25812.2 5.272 0.492 3 LNU278 25814.3 43.5 0.283 6 LNU220 25405.2 3.998 0.620 2 LNU43 14423.7 5.559 0.132 8 LNU278 25812.2 42.2 0.492 3 LNU234 25014.6 4.021 0.585 3 LNU45 25052.12 7.025 0.000 37 LNU43 14423.7 44.5 0.132 8 LNU234 25014.5 3.951 0.735 1 LNU45 25053.4 6.516 0.308 27 LNU45 25052.12 56.2 0.000 37 LNU236 25424.2 4.580 0.101 17 LNU45 25052.11 5.797 0.179 13 LNU45 25053.4 52.1 0.308 27 LNU236 25423.3 4.191 0.440 7 LNU45 25052.9 5.597 0.032 9 LNU45 25052.11 46.4 0.179 13 LNU236 25425.4 4.116 0.531 5 LNU67 25824.3 6.189 0.000 20 LNU45 25052.9 44.8 0.032 9 LNU236 25422.4 4.101 0.033 5 LNU67 25824.5 5.719 0.011 11 LNU67 25824.3 49.5 0.000 20 LNU24 24974.2 4.058 0.091 3 LNU67 25821.4 5.563 0.307 8 LNU67 25824.5 45.7 0.011 11 LNU24 24972.1 4.010 0.494 2 LNU9 25001.1 5.942 0.008 16 LNU67 25821.4 44.5 0.307 8 LNU25 14082.8 4.402 0.000 12 LNU9 25001.7 5.900 0.329 15 LNU9 25001.1 47.5 0.008 16 LNU25 14082.9 4.236 0.001 8 LNU9 25003.1 5.374 0.723 5 LNU9 25001.7 47.2 0.329 15 LNU25 14084.6 4.023 0.394 3 CONT. — 5.507 — 0 LNU9 25003.1 43.0 0.723 5 LNU25 14083.7 3.969 0.736 1 LNU10 25123.6 6.580 0.085 19 CONT. — 44.1 — 0 LNU267 25804.4 3.994 0.576 2 LNU10 25123.5 5.880 0.455 7 LNU10 25123.6 52.6 0.085 19 LNU271 25911.4 4.261 0.337 9 LNU157 24982.8 7.166 0.005 30 LNU10 25123.5 47.0 0.455 7 LNU271 25912.1 4.121 0.475 5 LNU157 24982.4 6.039 0.298 10 LNU157 24982.8 57.3 0.005 30 LNU278 25813.2 4.096 0.393 4 LNU157 24983.3 5.728 0.725 4 LNU157 24982.4 48.3 0.298 10 LNU278 25814.3 4.086 0.051 4 LNU173 25451.1 6.406 0.534 16 LNU157 24983.3 45.8 0.725 4 LNU278 25814.1 4.075 0.297 4 LNU178 14611.4 7.845 0.315 42 LNU173 25451.1 51.2 0.534 16 LNU278 25812.2 3.990 0.365 2 LNU178 14611.5 7.119 0.096 29 LNU178 14611.4 62.8 0.315 42 LNU43 14423.7 4.174 0.132 6 LNU178 14611.1 7.075 0.374 28 LNU178 14611.5 57.0 0.096 29 LNU43 14422.9 4.066 0.685 4 LNU184 25393.2 6.860 0.015 25 LNU178 14611.1 56.6 0.374 28 LNU45 25052.12 4.606 0.005 17 LNU184 25393.3 6.648 0.354 21 LNU184 25393.2 54.9 0.015 25 LNU45 25053.4 4.431 0.260 13 LNU184 25393.1 6.580 0.617 19 LNU184 25393.3 53.2 0.354 21 LNU45 25052.11 4.149 0.297 6 LNU184 25395.1 6.315 0.563 15 LNU184 25393.1 52.6 0.617 19 LNU45 25052.9 4.127 0.022 5 LNU230 25413.1 7.185 0.026 30 LNU184 25395.1 50.5 0.563 15 LNU67 25824.3 4.354 0.064 11 LNU230 25413.2 7.178 0.136 30 LNU230 25413.1 57.5 0.026 30 LNU67 25824.5 4.312 0.001 10 LNU230 25412.1 6.604 0.043 20 LNU230 25413.2 57.4 0.136 30 LNU67 25821.4 4.183 0.273 7 LNU230 25412.2 6.600 0.298 20 LNU230 25412.1 52.8 0.043 20 LNU9 25001.7 4.232 0.226 8 LNU230 25415.1 6.466 0.149 17 LNU230 25412.2 52.8 0.298 20 LNU9 25001.1 4.204 0.007 7 LNU236 25425.4 8.219 0.000 49 LNU230 25415.1 51.7 0.149 17 LNU9 25003.1 4.068 0.556 4 LNU236 25423.3 6.874 0.278 25 LNU236 25425.4 65.8 0.000 49 LNU9 25001.2 4.025 0.660 3 LNU236 25422.4 6.448 0.170 17 LNU236 25423.3 55.0 0.278 25 CONT. — 3.944 — 0 LNU236 25424.2 6.380 0.075 16 LNU236 25422.4 51.6 0.170 17 LNU10 25123.6 4.138 0.332 5 LNU24 24974.2 7.569 0.002 37 LNU236 25424.2 51.0 0.075 16 LNU157 24982.8 4.444 0.034 13 LNU24 24971.3 6.403 0.230 16 LNU24 24974.2 60.6 0.002 37 LNU157 24982.4 4.193 0.371 6 LNU24 24971.2 5.754 0.601 4 LNU24 24971.3 51.2 0.230 16 LNU173 25451.1 4.512 0.313 14 LNU24 24972.1 5.719 0.665 4 LNU24 24971.2 46.0 0.601 4 LNU173 25451.11 4.050 0.602 3 LNU263 25791.3 7.019 0.194 27 LNU24 24972.1 45.8 0.665 4 LNU178 14611.4 4.797 0.243 22 LNU263 25794.3 6.800 0.159 23 LNU263 25791.3 56.2 0.194 27 LNU178 14611.5 4.523 0.095 15 LNU263 25794.8 6.413 0.261 16 LNU263 25794.3 54.4 0.159 23 LNU178 14611.1 4.401 0.349 12 LNU263 25792.2 6.090 0.249 11 LNU263 25794.8 51.3 0.261 16 LNU184 25393.2 4.407 0.052 12 LNU276 25433.1 6.838 0.133 24 LNU263 25792.2 48.7 0.249 11 LNU184 25393.3 4.363 0.445 11 LNU276 25431.1 6.701 0.131 22 LNU276 25433.1 54.7 0.133 24 LNU184 25395.1 4.336 0.494 10 LNU276 25433.3 6.144 0.175 12 LNU276 25431.1 53.6 0.131 22 LNU184 25393.1 4.294 0.623 9 LNU279 25484.3 7.208 0.010 31 LNU276 25433.3 49.1 0.175 12 LNU20 24933.4 4.011 0.756 2 LNU279 25481.3 7.101 0.255 29 LNU279 25484.3 57.7 0.010 31 LNU230 25413.2 4.579 0.204 16 LNU279 25481.5 6.775 0.173 23 LNU279 25481.3 56.8 0.255 29 LNU230 25413.1 4.544 0.071 15 LNU279 25481.4 6.607 0.242 20 LNU279 25481.5 54.2 0.173 23 LNU230 25412.1 4.308 0.113 9 LNU279 25481.2 6.433 0.660 17 LNU279 25481.4 52.9 0.242 20 LNU230 25412.2 4.279 0.300 8 LNU36 25562.3 7.147 0.344 30 LNU279 25481.2 51.5 0.660 17 LNU230 25415.1 4.195 0.242 6 LNU36 25562.7 7.019 0.528 27 LNU36 25562.3 57.2 0.344 30 LNU236 25425.4 4.953 0.001 26 LNU36 25561.2 6.466 0.436 17 LNU36 25562.7 56.2 0.528 27 LNU236 25423.3 4.397 0.278 11 LNU56 24694.1 6.943 0.530 26 LNU36 25561.2 51.7 0.436 17 LNU236 25422.4 4.229 0.174 7 LNU56 24693.1 6.813 0.402 24 LNU56 24694.1 55.5 0.530 26 LNU236 25424.2 4.222 0.203 7 LNU56 24691.2 6.571 0.207 19 LNU56 24693.1 54.5 0.402 24 LNU24 24974.2 4.724 0.003 20 LNU56 24694.2 6.087 0.583 11 LNU56 24691.2 52.6 0.207 19 LNU24 24971.3 4.446 0.030 13 LNU73 25755.1 8.249 0.000 50 LNU56 24694.2 48.7 0.583 11 LNU24 24971.4 4.323 0.630 10 LNU73 25751.1 7.035 0.007 28 LNU73 25755.1 66.0 0.000 50 LNU24 24971.2 4.177 0.306 6 LNU73 25751.9 7.002 0.057 27 LNU73 25751.1 56.3 0.007 28 LNU24 24972.1 4.036 0.670 2 LNU73 25751.8 6.744 0.478 22 LNU73 25751.9 56.0 0.057 27 LNU263 25791.3 4.414 0.206 12 LNU73 25754.2 6.571 0.510 19 LNU73 25751.8 53.9 0.478 22 LNU263 25794.3 4.382 0.058 11 LNU9 25001.1 7.060 0.030 28 LNU73 25754.2 52.6 0.510 19 LNU263 25794.8 4.364 0.160 11 LNU9 25001.7 7.045 0.272 28 LNU9 25001.1 56.5 0.030 28 LNU263 25794.6 4.133 0.664 5 LNU9 25001.2 6.492 0.050 18 LNU9 25001.7 56.4 0.272 28 LNU263 25792.2 4.105 0.417 4 CONT. — 4.310 — 0 LNU9 25001.2 51.9 0.050 18 LNU276 25433.1 4.519 0.043 15 LNU131 14005.5 8.645 0.001 101 CONT. — 34.1 — 0 LNU276 25431.1 4.420 0.058 12 LNU131 14005.2 6.311 0.274 46 LNU131 14005.5 69.2 0.001 103 LNU276 25433.3 4.065 0.546 3 LNU131 14002.15 5.784 0.140 34 LNU131 14005.2 50.5 0.269 48 LNU276 25433.2 4.058 0.721 3 LNU135 26204.2 8.965 0.258 108 LNU131 14002.15 46.3 0.137 36 LNU279 25481.3 4.560 0.121 16 LNU135 26203.6 6.304 0.010 46 LNU135 26204.2 71.7 0.257 110 LNU279 25484.3 4.429 0.045 12 LNU135 26203.4 6.171 0.448 43 LNU135 26203.6 50.4 0.010 48 LNU279 25481.4 4.402 0.080 12 LNU135 26203.1 5.922 0.000 37 LNU135 26203.4 49.4 0.441 45 LNU279 25481.5 4.265 0.415 8 LNU135 26203.3 5.009 0.698 16 LNU135 26203.1 47.4 0.000 39 LNU279 25481.2 4.214 0.715 7 LNU161 14553.5 6.325 0.483 47 LNU135 26203.3 40.1 0.682 17 LNU36 25562.3 4.718 0.145 20 LNU161 14553.6 5.177 0.010 20 LNU161 14553.5 50.6 0.476 48 LNU36 25562.7 4.472 0.522 13 LNU173 25451.2 4.840 0.090 12 LNU161 14553.6 41.4 0.006 21 LNU36 25561.2 4.392 0.185 11 LNU173 25451.5 4.762 0.536 10 LNU173 25451.2 38.7 0.062 13 LNU36 25562.9 4.067 0.606 3 LNU181 25771.2 6.501 0.126 51 LNU173 25451.5 38.1 0.503 12 LNU53 25674.1 4.109 0.434 4 LNU181 25771.11 5.656 0.001 31 LNU173 25451.11 35.2 0.767 3 LNU56 24694.1 4.545 0.384 15 LNU181 25771.6 5.580 0.028 29 LNU181 25771.2 52.0 0.125 52 LNU56 24693.1 4.456 0.334 13 LNU181 25774.1 5.207 0.009 21 LNU181 25771.11 45.3 0.001 33 LNU56 24691.2 4.309 0.335 9 LNU181 25771.8 4.592 0.664 7 LNU181 25771.6 44.6 0.026 31 LNU56 24694.2 4.131 0.682 5 LNU181 25771.5 4.521 0.499 5 LNU181 25774.1 41.7 0.005 22 LNU73 25755.1 4.907 0.002 24 LNU184 25395.1 7.171 0.277 66 LNU181 25771.8 36.7 0.620 8 LNU73 25751.1 4.566 0.021 16 LNU184 25394.3 7.043 0.350 63 LNU181 25771.5 36.2 0.405 6 LNU73 25751.9 4.543 0.012 15 LNU184 25394.1 6.482 0.289 50 LNU184 25395.1 57.4 0.274 68 LNU73 25751.8 4.499 0.356 14 LNU184 25393.3 6.186 0.067 44 LNU184 25394.3 56.3 0.346 65 LNU73 25754.2 4.393 0.435 11 LNU184 25393.2 5.114 0.046 19 LNU184 25394.1 51.9 0.285 52 LNU9 25001.1 4.617 0.008 17 LNU184 25393.1 5.009 0.591 16 LNU184 25393.3 49.5 0.067 45 LNU9 25001.7 4.463 0.087 13 LNU224 25871.3 7.087 0.000 64 LNU184 25393.2 40.9 0.036 20 LNU9 25001.2 4.305 0.092 9 LNU224 25874.1 6.965 0.008 62 LNU184 25393.1 40.1 0.572 17 LNU9 25001.3 4.015 0.712 2 LNU224 25872.2 6.385 0.001 48 LNU224 25871.3 56.7 0.000 66 CONT. — 3.452 — 0 LNU224 25872.3 5.780 0.001 34 LNU224 25874.1 55.7 0.009 63 LNU131 14005.5 4.854 0.000 41 LNU224 25874.4 5.469 0.321 27 LNU224 25872.2 51.1 0.001 50 LNU131 14005.2 4.227 0.316 22 LNU246 25743.2 7.125 0.404 65 LNU224 25874.4 43.7 0.311 28 LNU131 14002.15 4.036 0.002 17 LNU246 25743.1 6.759 0.276 57 LNU224 25872.3 43.4 0.207 27 LNU135 26204.2 5.120 0.162 48 LNU246 25744.2 6.626 0.387 54 LNU246 25743.2 57.0 0.399 67 LNU135 26203.6 4.181 0.042 21 LNU246 25744.4 6.098 0.515 41 LNU246 25743.1 54.1 0.273 58 LNU135 26203.4 4.131 0.450 20 LNU246 25744.3 5.273 0.176 22 LNU246 25744.2 53.0 0.382 55 LNU135 26203.1 4.001 0.021 16 LNU250 25592.2 6.367 0.000 48 LNU246 25744.4 48.8 0.507 43 LNU135 26203.3 3.773 0.675 9 LNU250 25592.1 5.181 0.475 20 LNU246 25744.3 42.2 0.166 24 LNU161 14553.5 4.024 0.540 17 LNU250 25591.1 5.156 0.269 20 LNU250 25592.2 50.9 0.000 49 LNU161 14553.6 3.716 0.062 8 LNU260 26404.8 5.607 0.297 30 LNU250 25592.1 41.4 0.459 21 LNU173 25451.5 3.669 0.516 6 LNU260 26404.7 5.580 0.506 29 LNU250 25591.1 41.2 0.254 21 LNU173 25451.2 3.600 0.279 4 LNU260 26404.1 5.285 0.546 23 LNU260 26404.8 44.9 0.289 31 LNU173 25451.11 3.547 0.642 3 LNU260 26403.1 4.649 0.651 8 LNU260 26404.7 44.6 0.496 31 LNU181 25771.2 4.262 0.041 23 LNU260 26403.2 4.396 0.800 2 LNU260 26404.1 42.3 0.532 24 LNU181 25771.6 3.935 0.165 14 LNU276 25433.6 5.708 0.197 32 LNU260 26403.1 37.2 0.613 9 LNU181 25771.11 3.894 0.004 13 LNU276 25433.5 5.179 0.140 20 LNU260 26403.2 35.2 0.699 3 LNU181 25774.1 3.818 0.017 11 LNU276 25431.1 5.161 0.011 20 LNU276 25433.6 45.7 0.191 34 LNU181 25771.8 3.674 0.280 6 LNU276 25433.1 4.426 0.713 3 LNU276 25433.5 41.4 0.128 21 LNU184 25395.1 4.492 0.290 30 LNU279 25484.3 6.354 0.341 47 LNU276 25431.1 41.3 0.006 21 LNU184 25394.3 4.482 0.323 30 LNU279 25481.3 5.756 0.587 34 LNU276 25433.1 35.4 0.607 4 LNU184 25394.1 4.177 0.252 21 LNU279 25481.5 5.435 0.007 26 LNU279 25484.3 50.8 0.335 49 LNU184 25393.3 4.133 0.020 20 LNU279 25481.4 5.033 0.497 17 LNU279 25481.3 46.0 0.578 35 LNU184 25393.2 3.813 0.014 10 LNU3 26122.2 5.909 0.425 37 LNU279 25481.5 43.5 0.005 27 LNU184 25393.1 3.705 0.662 7 LNU33 25553.3 6.560 0.006 52 LNU279 25481.4 40.3 0.477 18 LNU224 25871.3 4.493 0.000 30 LNU33 25553.2 5.801 0.285 35 LNU3 26122.2 47.3 0.417 38 LNU224 25874.1 4.356 0.000 26 LNU33 25552.2 5.752 0.591 33 LNU33 25553.3 52.5 0.007 54 LNU224 25872.2 4.309 0.000 25 LNU33 25553.1 4.961 0.698 15 LNU33 25552.2 46.0 0.582 35 LNU224 25872.3 3.908 0.128 13 LNU53 25674.6 5.147 0.323 19 LNU33 25553.2 43.1 0.124 26 LNU224 25874.4 3.833 0.404 11 LNU56 24694.2 4.436 0.766 3 LNU33 25553.1 39.7 0.681 16 LNU246 25743.2 4.424 0.405 28 LNU73 25751.8 4.966 0.726 15 LNU53 25674.6 41.2 0.307 21 LNU246 25743.1 4.343 0.295 26 CONT. — 7.009 — 0 LNU56 24694.2 35.5 0.687 4 LNU246 25744.2 4.321 0.372 25 LNU119 26144.2. 7.422 0.040 6 LNU56 24693.1 35.2 0.768 3 LNU246 25744.4 4.129 0.544 20 LNU130 24913.6. 8.010 0.031 14 LNU73 25751.8 39.7 0.710 16 LNU246 25744.3 3.791 0.027 10 LNU130 24912.7. 8.000 0.563 14 CONT. — 56.1 — 0 LNU250 25592.2 4.190 0.000 21 LNU130 24914.5. 7.702 0.630 10 LNU119 26144.2. 59.4 0.040 6 LNU250 25591.1 3.850 0.300 12 LNU130 24911.7. 7.358 0.707 5 LNU130 24913.6. 64.1 0.031 14 LNU250 25592.1 3.821 0.500 11 LNU136 14511.10. 8.765 0.000 25 LNU130 24912.7. 64.0 0.563 14 LNU260 26404.7 3.957 0.497 15 LNU136 14515.5. 8.318 0.421 19 LNU130 24914.5. 61.6 0.630 10 LNU260 26404.8 3.890 0.165 13 LNU142 27541.1. 8.194 0.001 17 LNU130 24911.7. 58.9 0.707 5 LNU260 26404.1 3.770 0.526 9 LNU142 27546.1. 7.204 0.712 3 LNU136 14511.10. 70.1 0.000 25 LNU260 26403.1 3.649 0.489 6 LNU149 26175.3. 7.709 0.362 10 LNU136 14515.5. 66.5 0.421 19 LNU276 25433.6 3.990 0.171 16 LNU15 14123.11. 7.968 0.426 14 LNU142 27541.1. 65.6 0.001 17 LNU276 25431.1 3.781 0.144 10 LNU15 14123.13. 7.941 0.000 13 LNU142 27546.1. 57.6 0.712 3 LNU276 25433.5 3.747 0.110 9 LNU185 26474.2. 8.650 0.453 23 LNU149 26175.3. 57.6 0.306 3 LNU279 25484.3 4.239 0.327 23 LNU185 26475.1. 8.305 0.283 19 LNU15 14123.13. 63.5 0.000 13 LNU279 25481.3 4.086 0.519 18 LNU185 26474.1. 7.750 0.681 11 LNU15 14123.11. 60.1 0.749 7 LNU279 25481.5 3.904 0.006 13 LNU212 25833.2. 9.276 0.130 32 LNU185 26474.2. 69.2 0.453 23 LNU279 25481.4 3.752 0.483 9 LNU212 25834.4. 8.993 0.223 28 LNU185 26475.1. 66.4 0.283 19 LNU279 25481.2 3.509 0.721 2 LNU212 25834.5. 8.125 0.046 16 LNU185 26474.1. 62.0 0.681 11 LNU3 26122.2 4.147 0.367 20 LNU212 25832.1. 7.353 0.652 5 LNU212 25833.2. 74.2 0.130 32 LNU33 25553.3 4.335 0.017 26 LNU216 25985.4. 9.065 0.247 29 LNU212 25834.4. 71.9 0.223 28 LNU33 25552.2 4.067 0.541 18 LNU216 25982.1. 8.548 0.051 22 LNU212 25834.5. 65.0 0.046 16 LNU33 25553.2 3.973 0.017 15 LNU216 25984.1. 8.543 0.361 22 LNU212 25832.1. 58.8 0.652 5 LNU33 25553.1 3.716 0.678 8 LNU216 25984.6. 7.518 0.254 7 LNU216 25985.4. 72.5 0.247 29 LNU53 25674.6 3.826 0.360 11 LNU228 26224.7. 8.690 0.000 24 LNU216 25982.1. 68.4 0.051 22 LNU53 25674.3 3.496 0.751 1 LNU228 26222.4. 7.798 0.004 11 LNU216 25984.1. 68.3 0.361 22 LNU56 24694.2 3.551 0.538 3 LNU229 26112.3. 8.196 0.000 17 LNU216 25984.6. 60.1 0.254 7 LNU56 24693.1 3.515 0.785 2 LNU253 26241.1. 8.044 0.163 15 LNU228 26224.7. 69.5 0.000 24 LNU73 25751.8 3.799 0.677 10 LNU274 26261.3. 7.172 0.369 2 LNU228 26222.4. 62.4 0.004 11 CONT. — 4.516 — 0 LNU280 26162.1. 8.341 0.473 19 LNU229 26112.3. 65.6 0.000 17 LNU119 26144.2. 4.661 0.249 3 LNU55 26015.1. 7.969 0.422 14 LNU253 26241.1. 64.4 0.163 15 LNU130 24912.7. 5.046 0.322 12 LNU81 26031.9. 7.582 0.756 8 LNU274 26261.3. 57.4 0.369 2 LNU130 24914.5. 4.894 0.471 8 LNU81 26034.2. 7.572 0.684 8 LNU280 26162.1. 66.7 0.473 19 LNU130 24911.7. 4.783 0.342 6 CONT. — 6.912 — 0 LNU55 26015.1. 63.8 0.422 14 LNU130 24913.6. 4.731 0.324 5 LNU119 26141.1. 8.792 0.468 27 LNU81 26031.9. 60.7 0.756 8 LNU136 14511.10. 5.012 0.068 11 LNU119 26142.5. 7.376 0.586 7 LNU81 26034.2. 60.6 0.684 8 LNU136 14515.5. 4.893 0.486 8 LNU130 24913.5. 7.963 0.260 15 CONT. — 55.3 — 0 LNU142 27541.1. 5.007 0.001 11 LNU130 24914.5. 7.654 0.394 11 LNU119 26141.1. 70.3 0.468 27 LNU142 27546.1. 4.599 0.429 2 LNU130 24913.6. 7.350 0.664 6 LNU119 26142.5. 59.0 0.586 7 LNU149 26175.3. 4.779 0.002 6 LNU136 14515.1. 7.530 0.508 9 LNU130 24913.5. 63.7 0.260 15 LNU15 14123.13. 4.878 0.001 8 LNU136 14511.10. 7.444 0.692 8 LNU130 24914.5. 61.2 0.394 11 LNU15 14123.11. 4.818 0.550 7 LNU136 14514.8. 7.389 0.728 7 LNU130 24913.6. 58.8 0.664 6 LNU185 26474.2. 5.052 0.503 12 LNU142 27546.2. 7.551 0.642 9 LNU136 14515.1. 60.2 0.508 9 LNU185 26475.1. 4.953 0.147 10 LNU142 27546.1. 7.487 0.504 8 LNU136 14511.10. 59.6 0.692 8 LNU185 26474.1. 4.889 0.530 8 LNU142 27545.1. 7.329 0.792 6 LNU136 14514.8. 59.1 0.728 7 LNU212 25834.4. 5.219 0.236 16 LNU149 26174.7. 7.171 0.788 4 LNU142 27546.2. 60.4 0.642 9 LNU212 25833.2. 5.176 0.153 15 LNU15 14124.12. 8.132 0.349 18 LNU142 27546.1. 59.9 0.504 8 LNU212 25834.5. 5.085 0.167 13 LNU15 14122.8. 8.027 0.486 16 LNU142 27545.1. 58.6 0.792 6 LNU212 25834.1. 4.707 0.624 4 LNU15 14123.13. 7.620 0.415 10 LNU149 26174.7. 57.4 0.788 4 LNU212 25832.1. 4.689 0.346 4 LNU185 26474.1. 8.921 0.055 29 LNU15 14124.12. 65.1 0.349 18 LNU216 25982.1. 5.253 0.053 16 LNU212 25834.4. 8.727 0.084 26 LNU15 14122.8. 64.2 0.486 16 LNU216 25985.4. 5.187 0.306 15 LNU212 25834.5. 8.061 0.217 17 LNU15 14123.13. 61.0 0.415 10 LNU216 25984.1. 5.160 0.310 14 LNU212 25833.2. 7.256 0.683 5 LNU185 26474.1. 71.4 0.055 29 LNU216 25984.6. 4.889 0.000 8 LNU216 25985.4. 9.450 0.146 37 LNU212 25834.4. 69.8 0.084 26 LNU228 26224.7. 5.104 0.000 13 LNU216 25982.1. 7.955 0.280 15 LNU212 25834.5. 64.5 0.217 17 LNU228 26222.4. 4.805 0.198 6 LNU216 25984.6. 7.667 0.701 11 LNU212 25833.2. 58.1 0.683 5 LNU229 26112.3. 4.981 0.000 10 LNU216 25982.2. 7.312 0.641 6 LNU216 25985.4. 75.6 0.146 37 LNU253 26241.1. 4.900 0.000 9 LNU228 26225.2. 9.276 0.044 34 LNU216 25982.1. 63.6 0.280 15 LNU253 26245.1. 4.580 0.372 1 LNU228 26224.7. 8.572 0.399 24 LNU216 25984.6. 61.3 0.701 11 LNU274 26264.2. 4.699 0.606 4 LNU228 26222.4. 8.339 0.137 21 LNU216 25982.2. 58.5 0.641 6 LNU280 26162.1. 5.073 0.376 12 LNU228 26222.1. 8.289 0.164 20 LNU228 26225.2. 74.2 0.044 34 LNU55 26015.1. 4.909 0.385 9 LNU228 26224.6. 8.203 0.319 19 LNU228 26222.4. 66.7 0.137 21 LNU81 26034.2. 4.657 0.745 3 LNU229 26112.4. 8.649 0.257 25 LNU228 26222.1. 66.3 0.164 20 LNU81 26034.3. 4.588 0.501 2 LNU229 26111.7. 8.573 0.438 24 LNU228 26224.6. 65.6 0.319 19 CONT. — 4.514 — 0 LNU229 26111.5. 8.441 0.277 22 LNU228 26224.7. 58.7 0.616 6 LNU119 26141.1. 5.132 0.455 14 LNU229 26112.3. 8.225 0.344 19 LNU229 26112.4. 69.2 0.257 25 LNU119 26142.5. 4.717 0.517 4 LNU241 26232.4. 8.028 0.230 16 LNU229 26111.7. 68.6 0.438 24 LNU130 24913.5. 4.742 0.500 5 LNU241 26233.3. 7.906 0.658 14 LNU229 26111.5. 67.5 0.277 22 LNU130 24913.6. 4.712 0.574 4 LNU241 26234.1. 7.487 0.502 8 LNU229 26112.3. 65.8 0.344 19 LNU130 24914.5. 4.685 0.604 4 LNU253 26242.1. 7.550 0.652 9 LNU241 26232.4. 64.2 0.230 16 LNU136 14511.10. 4.806 0.556 6 LNU253 26241.1. 7.211 0.734 4 LNU241 26233.3. 63.2 0.658 14 LNU136 14514.8. 4.785 0.592 6 LNU274 26265.1. 7.782 0.634 13 LNU241 26234.1. 59.9 0.502 8 LNU136 14515.1. 4.727 0.548 5 LNU274 26262.2. 7.698 0.582 11 LNU253 26242.1. 60.4 0.652 9 LNU142 27546.2. 4.748 0.558 5 LNU280 26162.1. 8.526 0.144 23 LNU253 26241.1. 57.7 0.734 4 LNU142 27546.1. 4.712 0.515 4 LNU280 26164.4. 7.630 0.408 10 LNU274 26265.1. 62.3 0.634 13 LNU142 27545.1. 4.687 0.683 4 LNU55 26013.4. 7.698 0.433 11 LNU274 26262.2. 61.6 0.582 11 LNU15 14122.8. 4.959 0.461 10 LNU55 26015.1. 7.646 0.435 11 LNU280 26162.1. 68.2 0.144 23 LNU15 14123.13. 4.837 0.301 7 LNU55 26013.3. 7.634 0.782 10 LNU55 26013.4. 61.6 0.433 11 LNU15 14124.12. 4.773 0.572 6 LNU81 26031.10. 8.300 0.656 20 LNU55 26015.1. 61.2 0.435 11 LNU185 26474.1. 5.288 0.053 17 LNU81 26031.2. 7.932 0.410 15 LNU55 26013.3. 61.1 0.782 10 LNU185 26473.1. 4.624 0.722 2 CONTROL — 5.130 — 0.0 LNU81 26031.10. 66.4 0.656 20 LNU212 25834.4. 5.158 0.069 14 LNU61 26134.4 6.167 0.034 20.22 LNU81 26031.2. 63.5 0.410 15 LNU212 25834.5. 4.908 0.226 9 LNU61 26135.3 5.575 0.338 8.68 CONT. — 40.689 — 0.0 LNU212 25834.1. 4.682 0.593 4 CONT. — 5.130 — 0.0 LNU61 26134.4 49.340 0.02 21.26 LNU216 25985.4. 5.308 0.120 18 LNU115 27584.2 5.790 <0.4 12.9 LNU61 26135.3 44.604 0.33 9.62 LNU216 25982.1. 4.804 0.348 6 LNU115 27586.2 6.387 <0.1 24.5 CONT. — 40.689 — 0.0 LNU216 25982.2. 4.712 0.619 4 LNU115 27586.3 5.314 <0.7 3.6 LNU115 27584.2 46.316 <0.3 13.8 LNU216 25984.6. 4.658 0.782 3 LNU123 27721.1 5.768 <0.4 12.4 LNU115 27586.2 51.093 <0.1 25.6 LNU216 25984.1. 4.639 0.747 3 LNU123 27721.2 6.131 <0.4 19.5 LNU115 27586.3 42.513 <0.9 4.5 LNU228 26225.2. 5.360 0.060 19 LNU123 27722.1 6.229 <0.1 21.4 LNU123 27721.1 46.143 <0.3 13.4 LNU228 26224.7. 5.173 0.325 15 LNU123 27722.4 6.830 <0.1 33.1 LNU123 27721.2 49.044 <0.1 20.5 LNU228 26222.1. 5.005 0.185 11 LNU123 27724.1 5.298 <0.8 3.3 LNU123 27722.1 49.835 <0.1 22.5 LNU228 26224.6. 4.928 0.350 9 LNU123 27724.2 5.585 <0.6 8.9 LNU123 27722.4 54.642 <0.1 34.3 LNU228 26222.4. 4.759 0.423 5 LNU127 27601.2 6.811 <0.1 32.8 LNU123 27724.1 42.383 <0.9 4.2 LNU229 26111.7. 5.050 0.417 12 LNU127 27601.3 6.212 <0.1 21.1 LNU123 27724.2 44.676 <0.5 9.8 LNU229 26112.3. 5.016 0.412 11 LNU127 27601.4 7.362 <0.1 43.5 LNU127 27601.2 54.489 <0.1 33.9 LNU229 26112.4. 4.983 0.320 10 LNU127 27603.1 6.636 <0.1 29.3 LNU127 27601.3 49.696 <0.1 22.1 LNU229 26111.5. 4.884 0.337 8 LNU127 27603.5 6.058 <0.4 18.1 LNU127 27601.4 58.894 <0.1 44.7 LNU241 26233.3. 5.068 0.575 12 LNU134 29191.3 6.109 <0.4 19.1 LNU127 27603.1 53.084 <0.1 30.5 LNU241 26232.4. 5.012 0.163 11 LNU134 29191.6 5.673 <0.6 10.6 LNU127 27603.5 48.464 <0.3 19.1 LNU241 26234.1. 4.673 0.598 4 LNU134 29192.1 7.116 <0.1 38.7 LNU134 29191.3 48.868 <0.1 20.1 LNU253 26242.1. 4.850 0.331 7 LNU134 29193.2 5.921 <0.4 15.4 LNU134 29191.6 45.388 <0.5 11.5 LNU253 26241.1. 4.677 0.604 4 LNU190 27555.2 5.704 <0.6 11.2 LNU134 29192.1 56.931 <0.1 39.9 LNU274 26262.2. 4.923 0.343 9 LNU198 27731.2 5.550 <0.6 8.2 LNU134 29193.2 47.367 <0.3 16.4 LNU274 26265.1. 4.804 0.680 6 LNU198 27734.4 5.441 <0.8 6.1 LNU190 27555.2 45.636 <0.5 12.2 LNU280 26162.1. 5.140 0.227 14 LNU198 27735.4 5.535 <0.6 7.9 LNU198 27731.2 44.399 <0.5 9.1 LNU280 26164.4. 4.779 0.510 6 LNU200 27991.2 5.736 <0.6 11.8 LNU198 27734.4 43.531 <0.7 7.0 LNU55 26013.3. 4.868 0.663 8 LNU200 27992.2 5.827 <0.4 13.6 LNU198 27735.4 44.277 <0.5 8.8 LNU55 26013.4. 4.795 0.535 6 LNU200 27992.3 6.394 <0.1 24.6 LNU200 27991.2 45.887 <0.5 12.8 LNU55 26015.1. 4.687 0.636 4 LNU200 27993.4 6.850 <0.1 33.5 LNU200 27992.2 46.620 <0.3 14.6 LNU81 26031.10. 4.970 0.569 10 LNU200 27994.3 6.408 <0.1 24.9 LNU200 27992.3 51.155 <0.1 25.7 LNU81 26031.2. 4.792 0.582 6 LNU217 28231.3 6.348 <0.1 23.7 LNU200 27993.4 54.797 <0.1 34.7 CONT. — 4.055 — 0.0 LNU217 28234.1 6.165 <0.1 20.2 LNU200 27994.3 51.262 <0.1 26.0 LNU115 27584.2 4.302 <0.6 6.1 LNU244 28013.6 6.179 <0.1 20.4 LNU217 28231.3 50.780 <0.1 24.8 LNU115 27586.2 4.561 <0.1 12.5 LNU244 28013.8 6.185 <0.1 20.6 LNU217 28234.1 45.735 <0.5 12.4 LNU123 27721.1 4.234 <0.6 4.4 LNU244 28014.3 5.743 <0.6 11.9 LNU244 28013.6 49.429 <0.1 21.5 LNU123 27721.2 4.546 <0.1 12.1 LNU244 28014.4 6.687 <0.1 30.4 LNU244 28013.8 49.477 <0.1 21.6 LNU123 27722.1 4.427 0.25 9.2 LNU244 28015.1 6.208 <0.1 21.0 LNU244 28014.3 45.945 <0.5 12.9 LNU123 27722.4 4.726 <0.1 16.6 LNU262 27591.3 5.986 <0.4 16.7 LNU244 28014.4 53.499 <0.1 31.5 LNU123 27724.1 4.230 <0.6 4.3 LNU262 27591.7 6.332 <0.1 23.4 LNU244 28015.1 49.667 <0.1 22.1 LNU127 27601.2 4.661 <0.1 15.0 LNU262 27593.6 6.748 <0.1 31.5 LNU262 27591.3 47.887 <0.3 17.7 LNU127 27601.3 4.404 <0.25 8.6 LNU262 27595.4 6.770 <0.1 32.0 LNU262 27591.7 50.657 <0.1 24.5 LNU127 27601.4 4.689 <0.1 15.7 LNU266 27932.1 6.839 <0.1 33.3 LNU262 27593.6 53.987 <0.1 32.7 LNU127 27603.1 4.461 <0.25 10.0 LNU266 27935.3 5.920 <0.4 15.4 LNU262 27595.2 41.885 <0.9 2.9 LNU127 27603.5 4.477 <0.25 10.4 LNU266 27935.4 6.236 <0.1 21.6 LNU262 27595.4 54.162 <0.1 33.1 LNU134 29191.3 4.275 <0.6 5.4 LNU29 27651.3 5.393 <0.8 5.1 LNU266 27932.1 54.714 <0.1 34.5 LNU134 29192.1 4.774 <0.1 17.7 LNU29 27653.1 6.158 <0.1 20.0 LNU266 27935.3 47.363 <0.3 16.4 LNU190 27555.2 4.209 <0.7 3.8 LNU32 29251.1 5.634 <0.6 9.8 LNU266 27935.4 49.891 <0.1 22.6 LNU198 27734.4 4.216 <0.7 4.0 LNU32 29252.6 5.641 <0.6 10.0 LNU29 27651.3 43.145 <0.7 6.0 LNU200 27991.2 4.293 <0.6 5.9 LNU51 27611.1 5.810 <0.4 13.3 LNU29 27653.1 49.264 <0.1 21.1 LNU200 27992.2 4.337 <0.6 7.0 LNU51 27613.3 5.593 <0.6 9.0 LNU29 27654.1 41.748 <0.9 2.6 LNU200 27992.3 4.609 <0.1 13.7 LNU51 27614.2 5.505 <0.8 7.3 LNU32 29251.1 45.070 <0.5 10.8 LNU200 27993.4 4.754 <0.1 17.3 LNU58 27673.2 6.263 <0.1 22.1 LNU32 29252.6 45.129 <0.5 10.9 LNU200 27994.3 4.487 <0.25 10.7 LNU58 27673.3 5.560 <0.6 8.4 LNU51 27611.1 46.483 <0.3 14.2 LNU217 28231.3 4.431 <0.25 9.3 LNU58 27673.4 5.416 <0.8 5.6 LNU51 27613.3 44.746 <0.5 10.0 LNU217 28234.1 4.432 <0.25 9.3 LNU58 27673.6 5.456 <0.8 6.3 LNU51 27614.2 44.042 <0.5 8.2 LNU244 28013.6 4.470 <0.25 10.2 LNU58 27673.8 5.481 <0.8 6.8 LNU58 27673.2 50.103 <0.1 23.1 LNU244 28013.8 4.365 <0.6 7.6 CONT. 8252.24 1.222 — 0.0 LNU58 27673.3 44.483 <0.5 9.3 LNU244 28014.3 4.337 <0.6 7.0 LNU89 25325.1 1.521 0.03 24.5 LNU58 27673.4 43.332 <0.7 6.5 LNU244 28014.4 4.543 <0.1 12.0 LNU89 27193.2 1.438 0.11 17.7 LNU58 27673.8 43.851 <0.7 7.8 LNU244 28015.1 4.451 <0.25 9.8 CONT. — 8.301 — 0.0 LNU262 27591.3 4.358 <0.6 7.5 LNU89 25325.1 12.168 0.0005 46.6 LNU262 27591.7 4.642 <0.1 14.5 LNU89 27193.2 10.064 0.047 21.2 LNU262 27593.6 4.659 <0.1 14.9 LNU262 27595.4 4.664 <0.1 15.0 LNU266 27932.1 4.708 <0.1 16.1 LNU266 27935.3 4.412 <0.25 8.8 LNU266 27935.4 4.558 <0.1 12.4 LNU29 27653.1 4.643 <0.1 14.5 LNU32 29251.1 4.206 <0.7 3.7 LNU51 27614.2 4.177 <0.7 3.0 LNU58 27673.2 4.410 <0.25 8.8 LNU58 27673.3 4.331 <0.6 6.8 CONT. 8252.24 1.922 — 0.0 LNU89 25325.1 2.153 0.07 12.0 LNU89 27193.2 2.107 0.14 9.6 Table 79. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

The genes listed in Table 80 improved plant NUE when grown at limiting nitrogen concentration levels. These genes produced photosynthetic areas as seen by their larger leaf number, leaf blade area and petiole area. The genes were cloned under the regulation of a constitutive (At6669) and root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant.

TABLE 80 Genes showing improved plant photosynthetic capacity at limiting nitrogen growth conditions Leaf Blade Area Leaf Petiole Leaf Number [cm2] Length [cm] Gene Event P- % Gene Event P- % Gene Event P- % Name # Ave. Value incr. Name # Ave. Value incr. Name # Ave. Value incr. CONT. — 10.679 — 0 CONT. — 0.634 — 0 CONT. — 0.725 — 0 LNU100 14472.2 11.125 0.089 4 LNU100 14472.2 0.811 0.001 28 LNU100 14472.2 0.902 0.008 24 LNU100 14471.4 10.813 0.513 1 LNU100 14471.4 0.765 0.110 21 LNU100 14471.4 0.822 0.000 13 LNU104 25033.1 11.313 0.237 6 LNU100 14474.3 0.703 0.314 11 LNU100 14474.3 0.785 0.198 8 LNU104 25033.3 11.313 0.083 6 LNU100 14473.3 0.674 0.112 6 LNU100 14473.3 0.744 0.413 3 LNU104 25032.1 10.938 0.390 2 LNU104 25033.3 0.862 0.000 36 LNU104 25033.3 0.943 0.002 30 LNU106 14481.1 11.188 0.027 5 LNU104 25032.2 0.854 0.000 35 LNU104 25032.2 0.842 0.008 16 LNU106 14483.5 11.063 0.412 4 LNU104 25032.1 0.775 0.133 22 LNU104 25032.1 0.823 0.294 13 LNU114 25042.1 11.021 0.501 3 LNU104 25033.1 0.694 0.027 9 LNU104 25033.1 0.819 0.036 13 LNU155 14525.1 11.250 0.190 5 LNU104 25034.1 0.653 0.743 3 LNU104 25034.1 0.764 0.636 5 LNU155 14523.1 11.063 0.079 4 LNU106 14481.1 0.829 0.076 31 LNU106 14481.1 0.878 0.028 21 LNU218 24784.2 11.500 0.009 8 LNU106 14483.5 0.768 0.284 21 LNU106 14483.2 0.869 0.001 20 LNU218 24781.4 11.000 0.636 3 LNU106 14484.3 0.739 0.000 17 LNU106 14483.5 0.862 0.206 19 LNU218 24781.7 10.938 0.390 2 LNU106 14483.2 0.725 0.001 14 LNU106 14484.3 0.757 0.195 4 LNU218 24781.1 10.750 0.762 1 LNU114 25042.1 0.705 0.024 11 LNU114 25041.1 0.806 0.377 11 LNU23 25163.2 11.063 0.079 4 LNU114 25041.2 0.702 0.432 11 LNU114 25042.1 0.786 0.417 8 LNU23 25162.1 10.839 0.767 1 LNU114 25041.1 0.659 0.664 4 LNU114 25041.2 0.779 0.504 7 LNU23 25163.6 10.813 0.513 1 LNU155 14525.1 0.718 0.110 13 LNU155 14525.1 0.799 0.295 10 LNU28 25171.4 11.042 0.727 3 LNU155 14523.5 0.711 0.251 12 LNU155 14523.5 0.757 0.671 4 LNU28 25171.1 11.000 0.543 3 LNU213 24654.4 0.716 0.002 13 LNU213 24653.2 0.821 0.312 13 LNU28 25171.2 10.813 0.643 1 LNU218 24781.7 0.811 0.001 28 LNU213 24654.4 0.782 0.419 8 LNU4 25133.3 11.161 0.432 5 LNU218 24781.4 0.788 0.140 24 LNU218 24781.4 0.905 0.003 25 LNU40 24794.3 11.438 0.186 7 LNU218 24784.2 0.710 0.247 12 LNU218 24781.7 0.892 0.002 23 LNU40 24794.4 11.229 0.371 5 LNU218 24781.2 0.658 0.336 4 LNU218 24784.2 0.809 0.312 12 LNU40 24792.2 11.000 0.119 3 LNU23 25163.5 0.767 0.469 21 LNU218 24781.1 0.794 0.396 10 LNU46 14462.5 11.938 0.000 12 LNU23 25163.6 0.687 0.670 8 LNU23 25163.5 0.800 0.652 10 LNU46 14464.4 11.313 0.083 6 LNU23 25163.2 0.660 0.733 4 LNU23 25162.1 0.792 0.188 9 LNU46 14462.1 11.000 0.197 3 LNU28 25171.1 0.782 0.046 23 LNU23 25163.6 0.773 0.607 7 LNU46 14463.1 10.875 0.320 2 LNU28 25171.2 0.772 0.000 22 LNU23 25163.2 0.747 0.751 3 LNU48 24801.4 11.750 0.161 10 LNU28 25174.5 0.684 0.751 8 LNU28 25171.1 0.860 0.000 19 LNU48 24802.1 11.188 0.309 5 LNU4 25133.3 0.755 0.000 19 LNU28 25171.4 0.827 0.407 14 LNU48 24804.4 10.875 0.320 2 LNU4 25134.1 0.693 0.527 9 LNU28 25171.2 0.822 0.000 13 LNU63 24814.2 10.813 0.752 1 LNU4 25131.1 0.653 0.785 3 LNU28 25174.5 0.764 0.710 5 LNU8 25062.1 11.063 0.229 4 LNU40 24794.3 0.782 0.000 23 LNU4 25133.3 0.861 0.033 19 LNU8 25061.2 10.875 0.586 2 LNU40 24794.4 0.745 0.154 18 LNU4 25131.1 0.761 0.268 5 LNU8 25063.6 10.813 0.643 1 LNU46 14464.4 0.883 0.291 39 LNU4 25134.1 0.759 0.361 5 LNU94 24833.3 11.250 0.190 5 LNU46 14462.5 0.861 0.185 36 LNU40 24794.3 0.850 0.166 17 LNU96 25071.2 10.813 0.643 1 LNU46 14463.1 0.700 0.088 10 LNU40 24794.4 0.835 0.000 15 CONT. — 10.798 — 0 LNU46 14464.1 0.695 0.200 10 LNU40 24792.1 0.754 0.372 4 LNU113 25631.1 11.563 0.204 7 LNU46 14462.1 0.666 0.666 5 LNU40 24792.2 0.746 0.307 3 LNU120 25464.1 11.375 0.628 5 LNU48 24801.4 0.790 0.000 25 LNU46 14462.5 0.963 0.219 33 LNU120 25463.6 11.188 0.219 4 LNU48 24802.1 0.691 0.018 9 LNU46 14464.4 0.905 0.299 25 LNU120 25463.3 10.938 0.375 1 LNU48 24804.4 0.667 0.178 5 LNU46 14463.1 0.796 0.003 10 LNU120 25463.7 10.929 0.419 1 LNU63 24814.2 0.756 0.000 19 LNU46 14464.1 0.766 0.049 6 LNU124 14502.1 11.188 0.025 4 LNU63 24814.3 0.696 0.020 10 LNU46 14462.1 0.762 0.584 5 LNU124 14502.7 11.000 0.756 2 LNU63 24811.2 0.693 0.025 9 LNU48 24802.1 0.878 0.000 21 LNU124 14501.1 10.875 0.699 1 LNU7 25081.1 0.722 0.002 14 LNU48 24801.4 0.853 0.000 18 LNU132 14102.6 11.125 0.148 3 LNU7 25082.2 0.694 0.150 9 LNU48 24803.2 0.733 0.701 1 LNU132 14102.7 11.000 0.564 2 LNU8 25063.6 0.693 0.345 9 LNU63 24814.2 0.810 0.002 12 LNU140 14115.1 11.250 0.527 4 LNU8 25062.1 0.679 0.076 7 LNU63 24814.3 0.797 0.003 10 LNU148 25685.6 11.875 0.000 10 LNU8 25062.2 0.649 0.460 2 LNU63 24811.2 0.745 0.671 3 LNU148 25685.1 11.563 0.067 7 LNU8 25061.2 0.643 0.650 2 LNU7 25081.1 0.849 0.000 17 LNU148 25685.9 11.375 0.032 5 LNU94 24833.3 0.714 0.054 13 LNU7 25082.2 0.812 0.082 12 LNU287 24674.6 11.000 0.686 2 LNU96 25071.2 0.801 0.130 26 LNU7 25083.3 0.770 0.598 6 LNU37 14061.7 11.063 0.547 2 LNU96 25073.4 0.701 0.694 11 LNU8 25063.6 0.792 0.013 9 LNU5 14043.7 11.063 0.721 2 LNU96 25071.3 0.681 0.268 8 LNU8 25061.2 0.765 0.536 5 LNU5 14043.9 10.938 0.736 1 CONT. — 0.788 — 0 LNU8 25062.1 0.754 0.485 4 LNU72 24962.3 10.938 0.375 1 LNU113 25631.7 0.894 0.290 13 LNU94 24833.3 0.795 0.003 10 LNU74 25444.1 11.188 0.531 4 LNU113 25631.3 0.853 0.488 8 LNU96 25071.2 0.893 0.225 23 LNU74 25443.2 11.125 0.537 3 LNU140 14115.1 0.806 0.789 2 LNU96 25074.1 0.786 0.362 8 LNU87 24712.4 11.313 0.006 5 LNU148 25685.6 0.979 0.181 24 LNU96 25073.3 0.784 0.469 8 LNU87 24714.3 11.188 0.613 4 LNU148 25685.1 0.868 0.009 10 LNU96 25073.4 0.781 0.578 8 LNU98 25763.2 10.938 0.736 1 LNU5 14043.7 0.859 0.400 9 LNU96 25071.3 0.779 0.407 7 CONT. — 10.726 — 0 LNU68 14035.5 0.816 0.192 4 CONT. — 0.754 — 0 LNU113 25631.9 11.063 0.461 3 LNU74 25444.1 0.878 0.151 11 LNU113 25631.7 0.807 0.570 7 LNU113 25631.3 10.938 0.772 2 LNU74 25443.2 0.803 0.536 2 LNU113 25631.3 0.793 0.424 5 LNU120 25463.6 11.438 0.416 7 LNU98 25763.2 0.823 0.203 5 LNU113 25631.1 0.768 0.530 2 LNU124 14504.5 11.063 0.750 3 CONT. — 0.712 — 0 LNU120 25463.3 0.763 0.796 1 LNU148 25685.1 11.375 0.021 6 LNU113 25631.9 0.783 0.320 10 LNU124 14501.1 0.782 0.372 4 LNU148 25685.2 10.938 0.218 2 LNU120 25463.3 0.734 0.786 3 LNU132 14102.6 0.794 0.132 5 LNU72 24962.3 11.188 0.164 4 LNU148 25685.1 0.771 0.122 8 LNU140 14115.1 0.770 0.380 2 LNU72 24963.7 11.000 0.737 3 LNU72 24963.7 0.789 0.543 11 LNU148 25685.6 0.845 0.270 12 LNU74 25443.5 11.000 0.219 3 LNU72 24962.3 0.740 0.793 4 LNU148 25685.1 0.835 0.191 11 CONT. — 10.625 — 0 LNU98 25763.2 0.802 0.253 13 LNU287 24674.6 0.784 0.613 4 LNU117 25933.3 11.688 0.143 10 CONT. — 0.692 — 0 LNU5 14043.7 0.783 0.413 4 LNU117 25931.4 11.125 0.398 5 LNU117 25931.4 1.085 0.072 57 LNU74 25443.3 0.794 0.491 5 LNU117 25932.4 11.063 0.436 4 LNU117 25931.2 0.951 0.036 37 LNU74 25444.1 0.767 0.671 2 LNU117 25931.2 10.875 0.632 2 LNU117 25933.3 0.927 0.043 34 LNU74 25443.2 0.759 0.757 1 LNU122 25333.2 12.188 0.068 15 LNU117 25931.1 0.897 0.110 30 LNU87 24713.2 0.780 0.758 3 LNU122 25332.5 11.375 0.225 7 LNU117 25932.4 0.841 0.457 22 LNU98 25763.2 0.775 0.386 3 LNU122 25333.1 11.375 0.225 7 LNU122 25332.1 0.985 0.158 42 CONT. — 0.753 — 0 LNU122 25332.1 11.250 0.307 6 LNU122 25333.2 0.959 0.030 39 LNU113 25631.9 0.794 0.664 5 LNU122 25332.2 11.000 0.483 4 LNU122 25332.2 0.842 0.096 22 LNU148 25685.1 0.781 0.655 4 LNU125 25941.4 12.063 0.114 14 LNU122 25332.5 0.837 0.092 21 LNU72 24962.3 0.793 0.677 5 LNU125 25941.2 11.625 0.150 9 LNU122 25333.1 0.796 0.383 15 LNU98 25763.2 0.794 0.125 5 LNU125 25943.3 11.313 0.256 6 LNU125 25941.4 1.017 0.107 47 CONT. — 0.663 — 0 LNU125 25943.2 10.875 0.738 2 LNU125 25943.3 0.935 0.027 35 LNU117 25931.4 0.906 0.055 37 LNU125 25944.3 10.813 0.724 2 LNU125 25943.2 0.918 0.310 33 LNU117 25933.3 0.845 0.077 27 LNU138 14074.6 11.438 0.200 8 LNU125 25941.2 0.814 0.516 18 LNU117 25932.4 0.812 0.161 23 LNU138 14074.5 11.375 0.230 7 LNU125 25944.3 0.811 0.427 17 LNU117 25931.2 0.809 0.121 22 LNU138 14071.5 10.875 0.695 2 LNU138 14074.5 1.033 0.015 49 LNU117 25931.1 0.745 0.545 12 LNU180 24721.4 12.000 0.075 13 LNU138 14074.6 0.962 0.273 39 LNU122 25333.2 0.878 0.054 32 LNU180 24722.2 11.750 0.124 11 LNU138 14071.5 0.904 0.041 31 LNU122 25332.1 0.821 0.124 24 LNU180 24724.1 11.750 0.124 11 LNU138 14072.5 0.714 0.781 3 LNU122 25333.1 0.792 0.169 19 LNU180 24721.2 11.563 0.180 9 LNU180 24721.2 1.181 0.022 71 LNU122 25332.5 0.772 0.278 17 LNU180 24723.1 11.375 0.230 7 LNU180 24723.1 1.124 0.008 62 LNU122 25332.2 0.751 0.385 13 LNU220 25405.5 11.313 0.258 6 LNU180 24721.4 1.097 0.116 59 LNU125 25941.4 0.885 0.230 33 LNU220 25405.1 11.250 0.361 6 LNU180 24722.2 1.065 0.090 54 LNU125 25941.2 0.817 0.141 23 LNU220 25405.2 11.125 0.398 5 LNU180 24724.1 0.963 0.058 39 LNU125 25943.2 0.799 0.269 21 LNU220 25405.6 11.000 0.513 4 LNU220 25405.2 1.026 0.043 48 LNU125 25943.3 0.795 0.181 20 LNU220 25405.3 10.813 0.724 2 LNU220 25405.5 1.019 0.106 47 LNU125 25944.3 0.768 0.253 16 LNU230 25415.1 11.750 0.150 11 LNU220 25405.1 1.011 0.233 46 LNU138 14074.5 0.867 0.075 31 LNU230 25413.2 11.500 0.537 8 LNU220 25405.6 0.889 0.048 29 LNU138 14074.6 0.851 0.104 28 LNU230 25413.1 11.313 0.495 6 LNU220 25405.3 0.802 0.515 16 LNU138 14071.5 0.791 0.165 19 LNU230 25412.2 11.277 0.274 6 LNU230 25413.1 1.105 0.109 60 LNU138 14072.8 0.737 0.338 11 LNU230 25412.1 11.188 0.328 5 LNU230 25412.1 1.014 0.101 46 LNU180 24721.2 0.952 0.026 44 LNU234 25014.6 11.313 0.258 6 LNU230 25415.1 0.966 0.211 40 LNU180 24722.2 0.918 0.037 38 LNU234 25014.5 11.063 0.598 4 LNU230 25413.2 0.911 0.239 32 LNU180 24723.1 0.914 0.051 38 LNU234 25014.1 10.938 0.552 3 LNU230 25412.2 0.891 0.048 29 LNU180 24721.4 0.889 0.055 34 LNU234 25014.4 10.938 0.566 3 LNU234 25014.8 1.020 0.016 47 LNU180 24724.1 0.858 0.107 29 LNU25 14082.9 11.688 0.134 10 LNU234 25014.1 0.930 0.131 34 LNU220 25405.1 0.822 0.179 24 LNU25 14083.1 11.625 0.321 9 LNU234 25014.6 0.843 0.090 22 LNU220 25405.5 0.808 0.171 22 LNU25 14084.6 11.500 0.230 8 LNU234 25014.4 0.834 0.101 20 LNU220 25405.2 0.767 0.217 16 LNU25 14082.8 11.000 0.488 4 LNU234 25014.5 0.815 0.435 18 LNU220 25405.6 0.746 0.441 12 LNU254 25781.3 11.625 0.143 9 LNU25 14083.7 1.052 0.010 52 LNU220 25405.3 0.739 0.385 11 LNU254 25781.5 11.625 0.145 9 LNU25 14082.8 1.052 0.103 52 LNU230 25412.1 0.896 0.045 35 LNU254 25782.5 11.500 0.299 8 LNU25 14082.9 0.982 0.022 42 LNU230 25413.1 0.856 0.073 29 LNU254 25783.1 11.313 0.258 6 LNU25 14084.6 0.981 0.399 42 LNU230 25412.2 0.807 0.133 22 LNU254 25782.4 11.125 0.373 5 LNU25 14083.1 0.973 0.028 41 LNU230 25415.1 0.775 0.349 17 LNU263 25794.6 11.813 0.101 11 LNU254 25782.4 1.061 0.014 53 LNU230 25413.2 0.772 0.438 16 LNU263 25794.8 11.500 0.185 8 LNU254 25781.3 0.995 0.022 44 LNU234 25014.8 0.872 0.123 31 LNU263 25792.2 11.188 0.373 5 LNU254 25781.5 0.956 0.029 38 LNU234 25014.1 0.856 0.319 29 LNU263 25791.3 11.125 0.452 5 LNU254 25783.1 0.868 0.371 25 LNU234 25014.6 0.815 0.113 23 LNU263 25794.3 11.063 0.476 4 LNU254 25782.5 0.828 0.199 20 LNU234 25014.5 0.780 0.359 18 LNU267 25804.3 11.250 0.307 6 LNU263 25791.3 1.060 0.056 53 LNU234 25014.4 0.762 0.283 15 LNU267 25803.1 11.188 0.373 5 LNU263 25794.8 1.042 0.269 51 LNU25 14082.8 0.932 0.040 41 LNU267 25804.4 11.125 0.452 5 LNU263 25794.3 1.015 0.013 47 LNU25 14082.9 0.920 0.035 39 LNU267 25802.1 10.813 0.751 2 LNU263 25794.6 1.003 0.032 45 LNU25 14083.7 0.901 0.173 36 LNU271 25912.2 11.563 0.164 9 LNU263 25792.2 0.934 0.058 35 LNU25 14084.6 0.896 0.145 35 LNU271 25911.4 11.500 0.178 8 LNU267 25804.4 0.986 0.021 43 LNU25 14083.1 0.890 0.047 34 LNU271 25913.2 11.250 0.361 6 LNU267 25804.3 0.959 0.265 39 LNU254 25782.4 0.870 0.067 31 LNU271 25912.1 11.161 0.539 5 LNU267 25801.1 0.938 0.107 36 LNU254 25781.3 0.859 0.079 30 LNU271 25913.3 10.813 0.751 2 LNU267 25803.1 0.904 0.040 31 LNU254 25783.1 0.832 0.227 26 LNU278 25814.3 11.438 0.200 8 LNU267 25802.1 0.877 0.188 27 LNU254 25782.5 0.825 0.101 24 LNU278 25812.3 11.375 0.237 7 LNU271 25911.4 1.163 0.010 68 LNU254 25781.5 0.819 0.118 23 LNU278 25813.2 11.250 0.289 6 LNU271 25912.1 1.012 0.014 46 LNU263 25791.3 0.911 0.043 37 LNU278 25812.2 11.063 0.436 4 LNU271 25913.3 0.909 0.053 31 LNU263 25794.6 0.892 0.046 34 LNU36 25562.3 11.188 0.328 5 LNU271 25912.2 0.796 0.173 15 LNU263 25794.8 0.866 0.185 31 LNU36 25562.7 11.188 0.658 5 LNU278 25812.3 1.100 0.012 59 LNU263 25794.3 0.859 0.079 30 LNU36 25561.2 11.063 0.436 4 LNU278 25814.3 1.093 0.010 58 LNU263 25792.2 0.815 0.121 23 LNU43 14423.6 11.688 0.125 10 LNU278 25814.1 0.901 0.155 30 LNU267 25803.1 0.812 0.128 22 LNU43 14422.9 11.313 0.256 6 LNU278 25812.2 0.882 0.072 28 LNU267 25804.4 0.809 0.266 22 LNU43 14421.1 11.188 0.334 5 LNU278 25813.2 0.777 0.319 12 LNU267 25804.3 0.808 0.250 22 LNU43 14422.8 11.000 0.621 4 LNU36 25562.9 1.095 0.021 58 LNU267 25801.1 0.760 0.238 15 LNU45 25052.12 11.688 0.143 10 LNU36 25562.3 0.896 0.048 30 LNU267 25802.1 0.747 0.299 13 LNU45 25052.9 11.500 0.178 8 LNU36 25562.4 0.884 0.048 28 LNU271 25911.4 0.953 0.035 44 LNU45 25053.4 11.375 0.237 7 LNU36 25562.7 0.874 0.101 26 LNU271 25912.1 0.861 0.094 30 LNU45 25052.11 11.188 0.328 5 LNU36 25561.2 0.752 0.400 9 LNU271 25913.3 0.794 0.162 20 LNU45 25052.8 10.813 0.712 2 LNU43 14422.8 1.015 0.022 47 LNU271 25912.2 0.775 0.197 17 LNU67 25821.5 11.250 0.361 6 LNU43 14422.9 0.941 0.033 36 LNU271 25913.2 0.744 0.382 12 LNU67 25824.5 10.875 0.656 2 LNU43 14421.1 0.912 0.044 32 LNU278 25812.3 0.892 0.057 35 LNU67 25821.4 10.813 0.784 2 LNU43 14423.7 0.859 0.267 24 LNU278 25814.3 0.816 0.122 23 CONT. — 10.125 — 0 LNU43 14423.6 0.833 0.125 20 LNU278 25812.2 0.783 0.172 18 LNU100 14474.2 11.063 0.319 9 LNU45 25052.8 0.979 0.026 41 LNU278 25814.1 0.776 0.192 17 LNU100 14472.1 10.813 0.065 7 LNU45 25052.12 0.957 0.172 38 LNU278 25813.2 0.744 0.312 12 LNU100 14473.3 10.625 0.381 5 LNU45 25052.9 0.920 0.062 33 LNU36 25562.9 0.862 0.069 30 LNU100 14473.1 10.500 0.487 4 LNU45 25053.4 0.871 0.507 26 LNU36 25561.2 0.796 0.147 20 LNU104 25033.1 10.750 0.033 6 LNU45 25052.11 0.755 0.339 9 LNU36 25562.7 0.735 0.346 11 LNU104 25032.1 10.688 0.490 6 LNU67 25823.5 0.875 0.062 26 LNU36 25562.3 0.719 0.445 8 LNU104 25032.2 10.688 0.655 6 LNU67 25824.5 0.871 0.368 26 LNU36 25562.4 0.686 0.744 3 LNU104 25033.3 10.625 0.037 5 LNU67 25821.5 0.864 0.355 25 LNU43 14421.1 0.890 0.047 34 LNU106 14483.2 11.000 0.300 9 LNU67 25821.4 0.830 0.175 20 LNU43 14422.8 0.853 0.075 29 LNU106 14483.5 10.813 0.009 7 LNU67 25824.3 0.752 0.732 9 LNU43 14422.9 0.845 0.091 27 LNU106 14482.3 10.375 0.502 2 CONT. — 0.585 — 0 LNU43 14423.6 0.786 0.172 19 LNU106 14481.1 10.313 0.797 2 LNU100 14474.2 0.838 0.093 43 LNU43 14423.7 0.746 0.296 13 LNU106 14484.3 10.250 0.619 1 LNU100 14472.1 0.812 0.381 39 LNU45 25052.12 0.902 0.052 36 LNU114 25041.2 10.700 0.247 6 LNU100 14473.3 0.753 0.372 29 LNU45 25052.8 0.818 0.119 23 LNU114 25044.4 10.625 0.624 5 LNU100 14473.1 0.750 0.198 28 LNU45 25053.4 0.813 0.204 23 LNU114 25042.1 10.250 0.728 1 LNU100 14471.4 0.698 0.385 19 LNU45 25052.9 0.796 0.153 20 LNU117 25931.4 10.500 0.160 4 LNU104 25032.2 0.686 0.492 17 LNU45 25052.11 0.749 0.283 13 LNU117 25931.2 10.438 0.767 3 LNU104 25033.3 0.668 0.006 14 LNU67 25821.5 0.774 0.285 17 LNU117 25932.4 10.438 0.603 3 LNU104 25032.1 0.655 0.457 12 LNU67 25823.5 0.772 0.210 17 LNU155 14523.5 10.563 0.188 4 LNU104 25033.1 0.648 0.408 11 LNU67 25824.5 0.767 0.395 16 LNU180 24723.1 10.250 0.728 1 LNU106 14483.2 0.845 0.000 44 LNU67 25824.3 0.740 0.351 12 LNU218 24781.4 10.563 0.488 4 LNU106 14481.1 0.753 0.355 29 LNU67 25821.4 0.698 0.610 5 LNU254 25782.4 10.563 0.188 4 LNU106 14483.5 0.711 0.001 21 CONT. — 0.683 — 0 LNU4 25134.3 10.938 0.003 8 LNU106 14484.3 0.664 0.541 13 LNU100 14473.3 0.874 0.197 28 LNU4 25134.2 10.875 0.244 7 LNU114 25044.11 0.787 0.364 34 LNU100 14474.2 0.827 0.155 21 LNU40 24794.4 10.375 0.256 2 LNU114 25042.1 0.718 0.140 23 LNU100 14472.1 0.806 0.320 18 LNU40 24792.1 10.313 0.665 2 LNU114 25041.2 0.716 0.100 22 LNU100 14473.1 0.756 0.005 11 LNU46 14462.5 10.750 0.033 6 LNU114 25041.1 0.658 0.757 12 LNU104 25033.1 0.862 0.461 26 LNU46 14464.4 10.625 0.073 5 LNU117 25932.4 0.791 0.009 35 LNU104 25033.3 0.826 0.197 21 LNU46 14462.1 10.313 0.797 2 LNU117 25931.4 0.725 0.025 24 LNU104 25032.2 0.766 0.309 12 LNU48 24801.4 10.813 0.328 7 LNU117 25931.1 0.693 0.592 18 LNU104 25032.1 0.758 0.594 11 LNU48 24803.2 10.313 0.797 2 LNU117 25931.2 0.633 0.340 8 LNU106 14483.2 0.865 0.175 27 LNU63 24812.3 10.500 0.487 4 LNU117 25933.3 0.613 0.731 5 LNU106 14481.1 0.849 0.409 24 LNU7 25082.2 10.625 0.037 5 LNU155 14523.5 0.741 0.313 27 LNU106 14483.5 0.751 0.017 10 LNU8 25061.2 10.813 0.009 7 LNU155 14524.8 0.630 0.220 8 LNU106 14484.3 0.710 0.741 4 LNU8 25063.6 10.688 0.490 6 LNU180 24723.1 0.755 0.062 29 LNU114 25044.11 0.864 0.115 27 LNU94 24833.3 10.375 0.627 2 LNU180 24722.2 0.641 0.737 10 LNU114 25041.2 0.788 0.001 15 CONT. — 9.886 — 0 LNU218 24781.4 0.780 0.088 33 LNU114 25044.4 0.743 0.698 9 LNU122 25332.2 10.250 0.130 4 LNU218 24781.1 0.712 0.255 22 LNU114 25041.1 0.731 0.649 7 LNU122 25332.5 9.938 0.775 1 LNU218 24781.6 0.631 0.212 8 LNU114 25042.1 0.727 0.336 6 LNU125 25944.1 10.188 0.113 3 LNU218 24781.2 0.615 0.328 5 LNU117 25932.4 0.849 0.304 24 LNU220 25405.1 10.000 0.740 1 LNU254 25782.5 0.723 0.169 24 LNU117 25931.4 0.788 0.149 15 LNU236 25422.4 10.375 0.244 5 LNU4 25134.3 0.798 0.251 36 LNU117 25931.2 0.732 0.038 7 LNU236 25425.4 9.938 0.775 1 LNU4 25131.1 0.699 0.398 19 LNU117 25931.1 0.711 0.466 4 LNU45 25052.11 10.188 0.113 3 LNU4 25134.2 0.673 0.270 15 LNU155 14523.5 0.785 0.420 15 LNU45 25052.12 10.125 0.508 2 LNU4 25133.3 0.647 0.479 11 LNU180 24723.1 0.812 0.294 19 LNU45 25053.4 10.000 0.740 1 LNU40 24794.3 0.687 0.571 17 LNU180 24722.2 0.725 0.790 6 CONT. — 10.528 — 0 LNU40 24792.1 0.683 0.015 17 LNU218 24781.1 0.844 0.000 24 LNU10 25123.5 11.438 0.233 9 LNU40 24794.4 0.631 0.149 8 LNU218 24781.4 0.834 0.270 22 LNU10 25123.6 0.063 0.063 5 LNU46 14462.5 0.746 0.301 27 LNU218 24781.2 0.746 0.039 9 LNU157 24982.8 11.250 0.018 7 LNU46 14462.1 0.653 0.087 12 LNU254 25782.5 0.738 0.022 8 LNU173 25451.1 11.375 0.504 8 LNU46 14464.4 0.615 0.486 5 LNU4 25134.3 0.841 0.486 23 LNU173 25451.5 10.688 0.624 2 LNU48 24801.4 0.694 0.254 19 LNU4 25134.2 0.743 0.463 9 LNU178 14611.5 11.500 0.004 9 LNU48 24803.2 0.666 0.605 14 LNU4 25133.3 0.705 0.354 3 LNU178 14611.4 11.313 0.445 7 LNU63 24812.3 0.777 0.125 33 LNU40 24792.1 0.852 0.011 25 LNU178 14611.1 11.250 0.557 7 LNU63 24814.7 0.649 0.437 11 LNU40 24794.3 0.786 0.579 15 LNU184 25393.2 11.125 0.505 6 LNU63 24814.2 0.603 0.689 3 LNU40 24793.1 0.696 0.779 2 LNU184 25393.3 10.688 0.719 2 LNU7 25082.2 0.713 0.441 22 LNU40 24794.4 0.694 0.703 2 LNU230 25413.1 11.625 0.002 10 LNU7 25083.1 0.678 0.034 16 LNU46 14462.5 0.860 0.259 26 LNU230 25413.2 11.625 0.226 10 LNU7 25083.3 0.642 0.070 10 LNU46 14464.4 0.714 0.544 5 LNU230 25415.1 11.125 0.040 6 LNU8 25063.6 0.779 0.138 33 LNU48 24803.2 0.804 0.393 18 LNU230 25412.1 11.063 0.063 5 LNU8 25061.2 0.682 0.002 16 LNU48 24804.4 0.770 0.443 13 LNU230 25412.2 10.813 0.787 3 LNU94 24833.3 0.696 0.405 19 LNU48 24801.4 0.735 0.573 8 LNU236 25422.4 11.188 0.081 6 CONT. — 0.766 — 0 LNU63 24812.3 0.848 0.008 24 LNU236 25425.4 11.063 0.063 5 LNU10 25123.5 0.818 0.561 7 LNU63 24814.2 0.758 0.189 11 LNU236 25423.3 10.938 0.237 4 LNU122 25332.1 0.907 0.025 18 LNU63 24814.7 0.745 0.616 9 LNU236 25424.2 10.813 0.288 3 LNU122 25332.2 0.884 0.168 15 LNU7 25082.2 0.754 0.399 10 LNU24 24974.2 11.000 0.122 4 LNU122 25332.5 0.835 0.623 9 LNU7 25083.3 0.736 0.035 8 LNU24 24971.2 10.813 0.394 3 LNU125 25943.2 0.822 0.518 7 LNU7 25083.1 0.736 0.328 8 LNU24 24972.1 10.688 0.785 2 LNU125 25941.4 0.814 0.156 6 LNU8 25063.6 0.778 0.001 14 LNU263 25792.2 11.188 0.338 6 LNU138 14074.5 0.860 0.075 12 LNU8 25061.2 0.704 0.537 3 LNU263 25794.3 11.063 0.139 5 LNU138 14071.5 0.807 0.136 5 LNU94 24833.3 0.705 0.723 3 LNU263 25791.3 10.750 0.669 2 LNU138 14074.6 0.782 0.570 2 CONT. — 0.808 — 0 LNU276 25431.1 11.438 0.006 9 LNU157 24982.1 0.831 0.413 8 LNU122 25332.1 0.856 0.240 6 LNU276 25433.3 10.750 0.388 2 LNU178 14614.5 0.896 0.071 17 LNU122 25332.2 0.844 0.239 5 LNU276 25433.1 10.688 0.624 2 LNU178 14612.1 0.826 0.469 8 LNU122 25332.5 0.830 0.586 3 LNU279 25481.4 10.813 0.288 3 LNU178 14611.5 0.824 0.042 8 LNU138 14071.5 0.851 0.003 5 LNU279 25484.3 10.750 0.565 2 LNU178 14611.4 0.824 0.040 8 LNU138 14074.6 0.821 0.726 2 LNU36 25562.7 11.250 0.119 7 LNU220 25405.6 0.875 0.048 14 LNU178 14614.5 0.864 0.384 7 LNU36 25562.3 10.777 0.613 2 LNU220 25405.5 0.874 0.028 14 LNU178 14611.5 0.848 0.005 5 LNU36 25561.2 10.750 0.565 2 LNU220 25405.1 0.835 0.086 9 LNU234 25014.6 0.828 0.146 3 LNU56 24693.1 10.875 0.725 3 LNU220 25405.2 0.823 0.324 7 LNU236 25424.2 0.936 0.000 16 LNU56 24694.2 10.688 0.785 2 LNU234 25014.4 0.848 0.669 11 LNU236 25425.4 0.865 0.308 7 LNU73 25755.1 11.375 0.083 8 LNU234 25014.5 0.806 0.678 5 LNU236 25423.3 0.857 0.623 6 LNU73 25751.1 11.125 0.505 6 LNU236 25424.2 0.980 0.000 28 LNU236 25422.4 0.827 0.683 2 LNU73 25751.8 10.938 0.392 4 LNU236 25425.4 0.868 0.476 13 LNU25 14082.8 0.897 0.036 11 LNU73 25751.9 10.688 0.624 2 LNU236 25423.3 0.868 0.428 13 LNU25 14082.9 0.848 0.438 5 LNU9 25001.2 11.063 0.414 5 LNU236 25422.4 0.843 0.244 10 LNU267 25804.4 0.823 0.592 2 LNU9 25001.7 10.875 0.613 3 LNU24 24974.2 0.821 0.216 7 LNU271 25911.4 0.830 0.124 3 LNU9 25001.1 10.813 0.288 3 LNU24 24972.1 0.800 0.590 4 LNU271 25912.1 0.824 0.783 2 CONT. — 8.400 — 0 LNU25 14082.8 0.954 0.000 25 LNU278 25812.2 0.815 0.595 1 LNU131 14005.5 9.750 0.071 16 LNU25 14082.9 0.847 0.009 11 LNU43 14422.9 0.842 0.585 4 LNU131 14002.15 9.438 0.000 12 LNU25 14084.6 0.840 0.043 10 LNU43 14423.7 0.814 0.754 1 LNU131 14005.2 9.188 0.208 9 LNU25 14083.7 0.797 0.375 4 LNU45 25052.12 0.935 0.030 16 LNU135 26204.2 9.750 0.211 16 LNU267 25804.4 0.796 0.733 4 LNU45 25052.11 0.905 0.000 12 LNU135 26203.1 9.313 0.000 11 LNU271 25911.4 0.855 0.666 12 LNU45 25053.4 0.856 0.604 6 LNU135 26203.6 9.125 0.000 9 LNU271 25912.1 0.794 0.774 4 LNU45 25052.9 0.833 0.049 3 LNU135 26203.3 8.750 0.609 4 LNU278 25814.1 0.877 0.012 14 LNU67 25824.3 0.853 0.105 6 LNU161 14553.5 9.500 0.094 13 LNU278 25814.3 0.843 0.027 10 LNU67 25824.5 0.842 0.011 4 LNU161 14553.6 8.750 0.369 4 LNU278 25812.2 0.816 0.071 7 LNU67 25821.4 0.822 0.706 2 LNU173 25451.1 8.813 0.513 5 LNU278 25813.2 0.789 0.649 3 LNU9 25001.1 0.870 0.249 8 LNU173 25451.2 8.563 0.237 2 LNU43 14423.7 0.873 0.014 14 LNU9 25001.7 0.831 0.059 3 LNU173 25451.5 8.438 0.776 0 LNU43 14422.9 0.815 0.697 6 CONT. — 0.804 — 0 LNU181 25771.2 9.250 0.327 10 LNU45 25052.12 1.036 0.000 35 LNU10 25123.6 0.832 0.506 4 LNU181 25774.1 9.188 0.077 9 LNU45 25053.4 0.932 0.327 22 LNU157 24982.8 0.901 0.119 12 LNU181 25771.6 9.063 0.000 8 LNU45 25052.9 0.856 0.031 12 LNU157 24982.4 0.885 0.385 10 LNU181 25771.11 8.750 0.515 4 LNU45 25052.11 0.831 0.448 9 LNU157 24983.3 0.852 0.542 6 LNU184 25394.3 9.688 0.000 15 LNU67 25824.3 0.949 0.000 24 LNU173 25451.1 0.884 0.386 10 LNU184 25393.3 9.313 0.268 11 LNU67 25824.5 0.889 0.001 16 LNU173 25451.11 0.817 0.776 2 LNU184 25395.1 9.250 0.507 10 LNU67 25821.4 0.845 0.196 10 LNU178 14611.4 0.962 0.394 20 LNU184 25394.1 9.125 0.375 9 LNU9 25001.7 0.910 0.345 19 LNU178 14611.1 0.906 0.339 13 LNU184 25393.1 8.813 0.395 5 LNU9 25001.1 0.896 0.149 17 LNU178 14611.5 0.843 0.669 5 LNU224 25874.1 9.875 0.133 18 LNU9 25003.1 0.830 0.544 8 LNU184 25393.3 0.906 0.385 13 LNU224 25872.3 9.375 0.009 12 LNU9 25001.3 0.792 0.359 3 LNU184 25393.2 0.864 0.196 7 LNU224 25871.3 9.188 0.208 9 LNU9 25001.2 0.782 0.798 2 LNU184 25395.1 0.820 0.703 2 LNU224 25874.4 9.063 0.251 8 CONT. — 0.791 — 0 LNU230 25413.2 0.942 0.260 17 LNU224 25872.2 8.875 0.270 6 LNU10 25123.6 0.909 0.068 15 LNU230 25413.1 0.914 0.384 14 LNU246 25743.2 9.688 0.251 15 LNU157 24982.8 0.994 0.003 26 LNU230 25415.1 0.850 0.299 6 LNU246 25744.2 9.250 0.327 10 LNU157 24982.4 0.887 0.133 12 LNU230 25412.2 0.849 0.332 6 LNU246 25744.4 9.250 0.327 10 LNU157 24983.3 0.865 0.270 9 LNU230 25412.1 0.843 0.419 5 LNU246 25744.3 9.188 0.208 9 LNU168 24751.2 0.836 0.791 6 LNU236 25425.4 0.949 0.007 18 LNU246 25743.1 8.938 0.002 6 LNU173 25451.1 0.853 0.607 8 LNU236 25423.3 0.850 0.558 6 LNU250 25592.2 9.188 0.077 9 LNU178 14611.4 1.015 0.297 28 LNU24 24974.2 0.928 0.016 15 LNU250 25591.1 8.750 0.008 4 LNU178 14611.1 0.964 0.288 22 LNU24 24971.3 0.893 0.066 11 LNU250 25592.1 8.750 0.609 4 LNU178 14611.5 0.954 0.156 21 LNU24 24971.4 0.878 0.718 9 LNU250 25591.3 8.563 0.774 2 LNU184 25393.2 0.975 0.005 23 LNU24 24971.2 0.818 0.758 2 LNU250 25594.1 8.563 0.695 2 LNU184 25393.3 0.939 0.361 19 LNU263 25791.3 0.913 0.118 14 LNU260 26404.8 9.125 0.163 9 LNU184 25393.1 0.914 0.620 16 LNU263 25794.8 0.882 0.199 10 LNU260 26404.1 9.000 0.510 7 LNU184 25395.1 0.887 0.517 12 LNU263 25794.6 0.858 0.757 7 LNU260 26404.7 8.938 0.426 6 LNU184 25394.3 0.819 0.705 4 LNU263 25794.3 0.854 0.301 6 LNU260 26403.1 8.750 0.124 4 LNU230 25413.1 0.972 0.024 23 LNU276 25431.1 0.878 0.174 9 LNU276 25433.6 10.000 0.056 19 LNU230 25413.2 0.953 0.221 20 LNU276 25433.1 0.837 0.547 4 LNU276 25433.1 8.938 0.002 6 LNU230 25412.1 0.922 0.035 17 LNU279 25481.3 0.906 0.317 13 LNU276 25431.1 8.813 0.595 5 LNU230 25412.2 0.916 0.204 16 LNU279 25481.4 0.889 0.207 10 LNU276 25433.5 8.438 0.776 0 LNU230 25415.1 0.891 0.225 13 LNU279 25484.3 0.852 0.277 6 LNU279 25484.3 9.500 0.258 13 LNU236 25425.4 1.093 0.001 38 LNU279 25481.2 0.829 0.799 3 LNU279 25481.5 9.000 0.338 7 LNU236 25423.3 0.973 0.352 23 LNU36 25562.3 0.988 0.131 23 LNU279 25481.4 8.875 0.062 6 LNU236 25422.4 0.885 0.262 12 LNU36 25561.2 0.930 0.306 16 LNU279 25481.3 8.688 0.628 3 LNU236 25424.2 0.885 0.093 12 LNU36 25562.7 0.856 0.749 6 LNU3 26124.3 8.875 0.062 6 LNU24 24974.2 1.048 0.032 32 LNU53 25674.1 0.826 0.614 3 LNU3 26122.2 8.750 0.515 4 LNU24 24971.3 0.905 0.200 14 LNU56 24694.1 0.940 0.502 17 LNU33 25553.2 9.107 0.447 8 LNU263 25791.3 1.005 0.067 27 LNU56 24693.1 0.910 0.267 13 LNU33 25553.3 9.063 0.000 8 LNU263 25794.3 0.951 0.177 20 LNU56 24691.2 0.862 0.484 7 LNU33 25552.2 9.000 0.000 7 LNU263 25794.8 0.897 0.286 13 LNU56 24694.2 0.861 0.547 7 LNU53 25674.6 8.563 0.695 2 LNU263 25792.2 0.843 0.326 7 LNU73 25755.1 1.002 0.062 25 LNU56 24694.2 8.813 0.210 5 LNU276 25433.1 0.972 0.193 23 LNU73 25751.9 0.974 0.003 21 LNU56 24693.1 8.750 0.515 4 LNU276 25431.1 0.920 0.211 16 LNU73 25751.8 0.962 0.259 20 LNU73 25751.9 8.500 0.592 1 LNU276 25433.3 0.891 0.078 13 LNU73 25751.1 0.878 0.177 9 CONT. — 10.300 — 0 LNU276 25433.2 0.839 0.705 6 LNU73 25754.2 0.878 0.393 9 LNU130 24913.6. 10.625 0.391 3 LNU279 25481.3 0.999 0.223 26 LNU9 25001.1 0.934 0.049 16 LNU136 14511.10. 11.375 0.002 10 LNU279 25484.3 0.995 0.011 26 LNU9 25001.7 0.899 0.313 12 LNU136 14513.6. 10.563 0.174 3 LNU279 25481.5 0.973 0.141 23 LNU9 25003.1 0.886 0.650 10 LNU136 14515.5. 10.500 0.759 2 LNU279 25481.2 0.953 0.575 20 LNU9 25001.3 0.858 0.278 7 LNU136 14515.1. 10.375 0.666 1 LNU279 25481.4 0.920 0.251 16 LNU9 25001.2 0.833 0.627 4 LNU142 27546.1. 10.875 0.193 6 LNU36 25562.3 1.007 0.297 27 CONT. — 0.562 — 0 LNU142 27541.1. 10.500 0.264 2 LNU36 25562.7 0.933 0.623 18 LNU131 14005.5 0.869 0.001 55 LNU15 14123.13. 11.063 0.304 7 LNU36 25561.2 0.907 0.401 15 LNU131 14005.2 0.772 0.276 37 LNU15 14123.11. 10.917 0.474 6 LNU36 25562.4 0.829 0.518 5 LNU131 14002.15 0.714 0.004 27 LNU185 26474.2. 10.875 0.521 6 LNU53 25674.1 0.818 0.774 3 LNU131 14001.16 0.603 0.721 7 LNU185 26475.1. 10.750 0.424 4 LNU56 24694.1 0.987 0.484 25 LNU135 26204.2 0.930 0.182 66 LNU212 25833.2. 11.438 0.109 11 LNU56 24693.1 0.979 0.356 24 LNU135 26203.6 0.708 0.177 26 LNU212 25834.4. 11.250 0.358 9 LNU56 24691.2 0.926 0.180 17 LNU135 26203.3 0.686 0.434 22 LNU212 25834.5. 10.813 0.134 5 LNU56 24694.2 0.850 0.624 7 LNU135 26203.4 0.676 0.509 20 LNU212 25832.1. 10.500 0.573 2 LNU73 25755.1 1.109 0.000 40 LNU135 26203.1 0.647 0.276 15 LNU216 25984.1. 11.125 0.326 8 LNU73 25751.9 0.997 0.079 26 LNU161 14553.5 0.787 0.366 40 LNU216 25985.4. 10.688 0.056 4 LNU73 25751.1 0.985 0.011 25 LNU161 14552.7 0.603 0.548 7 LNU216 25984.6. 10.563 0.550 3 LNU73 25754.2 0.974 0.426 23 LNU173 25451.11 0.635 0.423 13 LNU228 26224.7. 11.000 0.456 7 LNU73 25751.8 0.965 0.469 22 LNU173 25451.5 0.585 0.523 4 LNU228 26222.4. 10.688 0.614 4 LNU9 25001.1 1.001 0.015 26 LNU181 25771.2 0.721 0.112 28 LNU228 26225.2. 10.625 0.632 3 LNU9 25001.7 0.979 0.222 24 LNU181 25774.1 0.651 0.165 16 LNU229 26111.7. 10.813 0.017 5 LNU9 25001.2 0.890 0.107 12 LNU181 25771.5 0.638 0.124 14 LNU229 26112.3. 10.750 0.270 4 LNU9 25001.3 0.821 0.598 4 LNU181 25771.6 0.637 0.042 13 LNU229 26112.6. 10.375 0.733 1 CONT. — 0.690 — 0 LNU181 25771.11 0.597 0.228 6 LNU241 26234.1. 10.938 0.520 6 LNU131 14005.5 1.234 0.000 79 LNU181 25771.8 0.577 0.596 3 LNU253 26241.1. 10.938 0.005 6 LNU131 14005.2 0.916 0.334 33 LNU184 25394.3 0.813 0.180 45 LNU274 26261.3. 10.625 0.391 3 LNU131 14002.15 0.843 0.195 22 LNU184 25393.3 0.799 0.071 42 LNU274 26265.1. 10.563 0.768 3 LNU135 26204.2 1.253 0.247 82 LNU184 25394.1 0.755 0.192 34 LNU280 26162.1. 10.580 0.507 3 LNU135 26203.6 0.954 0.040 38 LNU184 25395.1 0.719 0.636 28 LNU280 26164.4. 10.479 0.461 2 LNU135 26203.4 0.904 0.479 31 LNU184 25393.1 0.640 0.376 14 LNU55 26015.1. 10.563 0.174 3 LNU135 26203.1 0.874 0.039 27 LNU184 25393.2 0.634 0.177 13 LNU81 26034.2. 10.750 0.270 4 LNU135 26203.3 0.790 0.705 15 LNU224 25871.3 0.797 0.041 42 LNU81 26031.2. 10.688 0.056 4 LNU161 14553.5 0.916 0.565 33 LNU224 25872.2 0.751 0.000 34 LNU81 26031.9. 10.563 0.656 3 LNU161 14553.6 0.776 0.049 12 LNU224 25874.1 0.726 0.011 29 CONT. — 10.021 — 0 LNU173 25451.5 0.736 0.714 7 LNU224 25872.3 0.690 0.203 23 LNU119 26144.1. 10.500 0.098 5 LNU173 25451.2 0.718 0.488 4 LNU224 25874.4 0.662 0.314 18 LNU119 26142.5. 10.313 0.280 3 LNU181 25771.2 0.966 0.125 40 LNU246 25743.2 0.819 0.360 46 LNU130 24914.5. 10.688 0.037 7 LNU181 25771.11 0.876 0.000 27 LNU246 25744.4 0.760 0.459 35 LNU130 24913.6. 10.500 0.124 5 LNU181 25771.6 0.862 0.004 25 LNU246 25744.2 0.744 0.439 32 LNU130 24913.5. 10.313 0.280 3 LNU181 25774.1 0.763 0.105 11 LNU246 25743.1 0.712 0.087 27 LNU136 14511.10. 10.688 0.430 7 LNU181 25771.8 0.751 0.478 9 LNU246 25744.3 0.653 0.399 16 LNU136 14514.8. 10.500 0.124 5 LNU181 25771.5 0.731 0.334 6 LNU250 25592.2 0.752 0.213 34 LNU136 14515.1. 10.438 0.506 4 LNU184 25395.1 1.054 0.264 53 LNU250 25591.1 0.673 0.248 20 LNU136 14515.5. 10.438 0.506 4 LNU184 25394.3 1.053 0.371 53 LNU250 25592.1 0.640 0.589 14 LNU142 27546.2. 10.250 0.779 2 LNU184 25394.1 0.951 0.294 38 LNU250 25591.3 0.582 0.622 4 LNU142 27546.1. 10.188 0.607 2 LNU184 25393.3 0.929 0.024 35 LNU260 26404.8 0.683 0.025 22 LNU149 26174.7. 10.250 0.424 2 LNU184 25393.2 0.782 0.035 13 LNU260 26404.1 0.679 0.418 21 LNU15 14123.13. 10.875 0.015 9 LNU184 25393.1 0.753 0.732 9 LNU260 26403.1 0.656 0.142 17 LNU15 14124.12. 10.688 0.037 7 LNU224 25871.3 1.095 0.000 59 LNU260 26403.2 0.622 0.084 11 LNU15 14122.9. 10.313 0.628 3 LNU224 25874.1 1.000 0.000 45 LNU260 26404.7 0.619 0.672 10 LNU185 26474.1. 10.500 0.124 5 LNU224 25872.2 0.981 0.000 42 LNU276 25433.6 0.741 0.251 32 LNU185 26475.1. 10.125 0.677 1 LNU224 25872.3 0.841 0.025 22 LNU276 25431.1 0.651 0.008 16 LNU212 25834.4. 11.063 0.198 10 LNU224 25874.4 0.807 0.382 17 LNU276 25433.1 0.598 0.619 6 LNU212 25834.1. 10.750 0.027 7 LNU246 25743.1 1.000 0.316 45 LNU279 25481.5 0.724 0.000 29 LNU212 25834.5. 10.375 0.512 4 LNU246 25743.2 0.986 0.464 43 LNU279 25481.3 0.695 0.581 24 LNU212 25833.1. 10.188 0.607 2 LNU246 25744.2 0.977 0.436 42 LNU279 25484.3 0.694 0.583 24 LNU216 25982.2. 11.188 0.081 12 LNU246 25744.4 0.900 0.570 30 LNU279 25481.2 0.592 0.694 5 LNU216 25985.4. 11.000 0.009 10 LNU246 25744.3 0.766 0.516 11 LNU3 26122.2 0.726 0.545 29 LNU216 25982.1. 10.938 0.234 9 LNU250 25592.2 0.925 0.000 34 LNU3 26124.3 0.684 0.377 22 LNU216 25984.6. 10.313 0.746 3 LNU250 25591.1 0.792 0.492 15 LNU3 26123.5 0.643 0.491 15 LNU228 26225.2. 10.938 0.033 9 LNU250 25592.1 0.772 0.626 12 LNU3 26124.1 0.627 0.549 12 LNU228 26224.7. 10.771 0.553 7 LNU260 26404.7 0.835 0.567 21 LNU33 25553.3 0.772 0.058 37 LNU228 26222.4. 10.750 0.027 7 LNU260 26404.1 0.830 0.519 20 LNU33 25552.2 0.729 0.384 30 LNU228 26224.6. 10.375 0.672 4 LNU260 26404.8 0.822 0.210 19 LNU33 25553.2 0.703 0.091 25 LNU228 26222.1. 10.313 0.280 3 LNU276 25433.6 0.852 0.275 23 LNU33 25553.1 0.699 0.464 24 LNU229 26112.3. 10.938 0.394 9 LNU276 25433.5 0.811 0.162 17 LNU53 25674.6 0.675 0.202 20 LNU229 26111.5. 10.688 0.336 7 LNU276 25431.1 0.795 0.020 15 LNU53 25674.3 0.621 0.284 11 LNU229 26112.4. 10.625 0.175 6 LNU279 25481.3 0.943 0.510 37 LNU56 24694.2 0.667 0.187 19 LNU229 26111.7. 10.375 0.377 4 LNU279 25484.3 0.927 0.303 34 LNU56 24693.1 0.623 0.497 11 LNU241 26233.3. 10.313 0.697 3 LNU279 25481.5 0.884 0.004 28 LNU73 25751.8 0.621 0.689 11 LNU241 26232.4. 10.125 0.781 1 LNU279 25481.4 0.754 0.618 9 CONT. — 0.920 — 0 LNU253 26242.1. 10.375 0.672 4 LNU3 26122.2 0.888 0.481 29 LNU130 24912.7. 0.993 0.491 8 LNU274 26265.1. 10.625 0.065 6 LNU33 25553.3 0.988 0.000 43 LNU130 24911.7. 0.932 0.736 1 LNU274 26261.3. 10.375 0.607 4 LNU33 25552.2 0.881 0.639 28 LNU130 24913.6. 0.928 0.690 1 LNU274 26264.2. 10.250 0.659 2 LNU33 25553.2 0.860 0.276 25 LNU136 14511.10. 1.024 0.000 11 LNU280 26164.4. 10.652 0.132 6 LNU33 25553.1 0.793 0.638 15 LNU136 14514.8. 0.976 0.214 6 LNU280 26162.1. 10.438 0.506 4 LNU53 25674.6 0.831 0.271 20 LNU142 27546.1. 0.931 0.592 1 LNU55 26013.4. 10.563 0.072 5 LNU56 24694.2 0.718 0.699 4 LNU149 26175.3. 0.950 0.244 3 LNU55 26013.3. 10.438 0.734 4 LNU73 25751.8 0.793 0.713 15 LNU15 14123.13. 0.985 0.389 7 LNU55 26013.9. 10.313 0.383 3 CONT. — 0.998 — 0 LNU15 14123.11. 0.973 0.646 6 LNU81 26031.2. 10.813 0.019 8 LNU119 26144.2. 1.111 0.000 11 LNU15 14122.8. 0.927 0.724 1 LNU81 26031.10. 10.500 0.637 5 LNU130 24912.7. 1.170 0.471 17 LNU185 26475.1. 1.017 0.001 11 LNU130 24913.6. 1.124 0.000 13 LNU185 26474.1. 1.017 0.224 11 LNU130 24914.5. 1.091 0.507 9 LNU185 26474.2. 1.012 0.558 10 LNU130 24911.7. 1.065 0.479 7 LNU212 25834.4. 1.093 0.186 19 LNU136 14511.10. 1.152 0.000 15 LNU212 25834.5. 1.044 0.000 14 LNU136 14515.5. 1.131 0.504 13 LNU212 25833.2. 1.029 0.044 12 LNU142 27541.1. 1.162 0.162 16 LNU212 25834.1. 1.003 0.439 9 LNU149 26175.3. 1.088 0.262 9 LNU212 25832.1. 0.977 0.024 6 LNU15 14123.11. 1.074 0.619 8 LNU216 25982.1. 1.110 0.000 21 LNU15 14123.13. 1.060 0.270 6 LNU216 25984.1. 1.095 0.394 19 LNU185 26474.2. 1.181 0.474 18 LNU216 25984.6. 1.011 0.199 10 LNU185 26475.1. 1.164 0.276 17 LNU216 25985.4. 1.008 0.361 10 LNU185 26474.1. 1.075 0.648 8 LNU216 25982.2. 0.946 0.569 3 LNU212 25833.2. 1.253 0.141 26 LNU228 26222.4. 0.994 0.311 8 LNU212 25834.4. 1.144 0.191 15 LNU228 26224.7. 0.980 0.433 7 LNU212 25834.5. 1.137 0.293 14 LNU228 26224.6. 0.974 0.335 6 LNU212 25832.1. 1.024 0.771 3 LNU229 26112.3. 1.010 0.108 10 LNU216 25985.4. 1.190 0.281 19 LNU229 26111.7. 0.932 0.754 1 LNU216 25982.1. 1.189 0.144 19 LNU253 26241.1. 0.970 0.691 5 LNU216 25984.1. 1.159 0.328 16 LNU274 26262.2. 0.933 0.628 1 LNU216 25984.6. 1.047 0.057 5 LNU280 26162.1. 1.053 0.427 15 LNU228 26224.7. 1.169 0.003 17 LNU81 26031.9. 0.939 0.770 2 LNU228 26222.4. 1.089 0.204 9 LNU81 26034.2. 0.931 0.798 1 LNU229 26112.3. 1.154 0.000 16 CONT. — 0.912 — 0 LNU253 26241.1. 1.110 0.200 11 LNU119 26142.5. 0.983 0.375 8 LNU253 26245.1. 1.050 0.357 5 LNU119 26141.1. 0.981 0.501 8 LNU274 26261.3. 1.028 0.543 3 LNU136 14514.8. 0.989 0.455 8 LNU277 25844.4. 1.059 0.506 6 LNU136 14511.10. 0.982 0.508 8 LNU280 26162.1. 1.139 0.546 14 LNU142 27546.2. 0.967 0.635 6 LNU55 26015.1. 1.133 0.325 14 LNU142 27545.1. 0.962 0.742 6 LNU81 26031.9. 1.080 0.744 8 LNU149 26174.7. 0.936 0.711 3 LNU81 26034.2. 1.063 0.673 6 LNU15 14122.8. 1.050 0.456 15 CONT. — 0.973 — 0 LNU15 14123.13. 0.994 0.220 9 LNU119 26141.1. 1.245 0.391 28 LNU15 14122.9. 0.966 0.725 6 LNU119 26142.8. 1.071 0.613 10 LNU15 14124.12. 0.932 0.764 2 LNU119 26142.5. 1.063 0.417 9 LNU185 26474.1. 1.126 0.129 23 LNU130 24913.5. 1.121 0.205 15 LNU185 26473.1. 0.976 0.332 7 LNU130 24914.5. 1.060 0.457 9 LNU212 25834.4. 1.075 0.053 18 LNU130 24912.7. 1.044 0.766 7 LNU212 25834.1. 0.952 0.524 4 LNU130 24913.6. 1.041 0.655 7 LNU212 25833.2 0.940 0.733 3 LNU136 14515.1. 1.065 0.451 9 LNU216 25985.4. 1.081 0.242 19 LNU136 14514.8. 1.048 0.675 8 LNU216 25982.0 1.023 0.157 12 LNU136 14511.10. 1.040 0.682 7 LNU216 25982.1. 1.010 0.295 11 LNU142 27546.1. 1.048 0.483 8 LNU216 25984.6. 0.974 0.511 7 LNU142 27546.2. 1.048 0.622 8 LNU228 26225.2. 1.054 0.065 16 LNU149 26174.7. 1.017 0.729 5 LNU228 26222.4. 1.004 0.233 10 LNU15 14124.12. 1.132 0.340 16 LNU228 26222.1. 0.978 0.304 7 LNU15 14122.8. 1.119 0.482 15 LNU228 26224.6. 0.951 0.727 4 LNU15 14123.11. 1.082 0.717 1 LNU229 26111.5. 1.050 0.063 15 LNU15 14123.13. 1.052 0.469 8 LNU229 26112.3. 1.039 0.668 14 LNU185 26474.1. 1.258 0.042 29 LNU229 26111.7. 1.035 0.371 13 LNU185 26473.1. 1.004 0.773 3 LNU229 26112.4. 0.971 0.420 6 LNU212 25834.4. 1.176 0.138 21 LNU253 26242.1. 0.986 0.260 8 LNU212 25834.5. 1.099 0.265 13 LNU253 26241.1. 0.953 0.786 4 LNU212 25833.2. 1.063 0.408 9 LNU274 26262.2. 0.967 0.439 6 LNU216 25985.4. 1.248 0.201 28 LNU280 26162.1. 1.023 0.127 12 LNU216 25984.6. 1.077 0.653 11 LNU55 26013.4. 0.969 0.639 6 LNU216 25982.1. 1.068 0.386 10 LNU55 26013.9. 0.936 0.738 3 LNU216 25984.1. 1.025 0.757 5 LNU81 26031.2. 1.025 0.455 12 LNU228 26225.2. 1.254 0.054 29 LNU81 26031.10. 0.974 0.759 7 LNU228 26222.1. 1.154 0.136 19 LNU228 26224.7. 1.153 0.423 19 LNU228 26222.4. 1.135 0.165 17 LNU228 26224.6. 1.123 0.227 15 LNU229 26112.4. 1.185 0.331 22 LNU229 26111.7. 1.176 0.394 21 LNU229 26111.5. 1.160 0.295 19 LNU229 26112.3. 1.129 0.305 16 LNU241 26233.3. 1.137 0.596 17 LNU241 26234.1. 1.068 0.385 10 LNU241 26232.4. 1.065 0.399 9 LNU253 26242.1. 1.053 0.632 8 LNU253 26241.1. 1.045 0.505 7 LNU274 26265.1. 1.098 0.634 13 LNU274 26262.2. 1.056 0.558 8 LNU280 26162.1. 1.190 0.211 22 LNU55 26015.1. 1.104 0.272 13 LNU55 26013.4. 1.084 0.388 11 LNU81 26031.10. 1.169 0.541 20 LNU81 26031.2. 1.089 0.427 12 Table 80. “CONT.” - Control; “Ave.” - Average; “% Incr.” = % increment.

The genes listed in Table 81 improved plant NUE when grown at standard nitrogen concentration levels. These genes produced faster developing plants when grown under limiting nitrogen growth conditions, compared to control plants as measured by growth rate of rosette area, rosette diameter and plot coverage. The genes were cloned under the regulation of a constitutive (At6669) and root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant.

TABLE 81 Genes showing improved rosette growth performance at limiting nitrogen growth conditions RGR Of Rosette RGR Of Rosette RGR Of Plot Area Diameter Coverage Gene Event P- % Gene Event P- % Gene Event P- % Name # Ave. Value incr. Name # Ave. Value incr. Name # Ave. Value incr. CONT. — 0.488 — 0 CONT. — 0.279 — 0 CONT. — 3.86 — 0 LNU100 14472.2 0.673 0.007 38 LNU100 14472.2 0.341 0.009 22 LNU100 14472.2 5.39 0.008 39 LNU100 14471.4 0.573 0.204 17 LNU100 14471.4 0.314 0.127 13 LNU100 14471.4 4.59 0.190 19 LNU104 25033.3 0.708 0.002 45 LNU100 14474.3 0.294 0.500 5 LNU100 14474.3 4.01 0.785 4 LNU104 25032.2 0.654 0.019 34 LNU100 14473.3 0.293 0.539 5 LNU104 25033.3 5.66 0.002 47 LNU104 25032.1 0.590 0.122 21 LNU104 25033.3 0.359 0.001 29 LNU104 25032.2 5.24 0.018 36 LNU104 25033.1 0.539 0.432 10 LNU104 25032.1 0.321 0.078 15 LNU104 25032.1 4.72 0.115 22 LNU106 14481.1 0.646 0.025 32 LNU104 25032.2 0.315 0.115 13 LNU104 25033.1 4.31 0.400 12 LNU106 14483.5 0.591 0.140 21 LNU104 25033.1 0.299 0.369 7 LNU106 14481.1 5.17 0.024 34 LNU106 14483.2 0.555 0.315 14 LNU106 14481.1 0.341 0.015 22 LNU106 14483.5 4.73 0.132 22 LNU106 14484.3 0.543 0.412 11 LNU106 14483.5 0.331 0.042 19 LNU106 14483.2 4.44 0.292 15 LNU114 25041.2 0.534 0.497 9 LNU106 14483.2 0.305 0.245 9 LNU106 14484.3 4.34 0.381 13 LNU114 25042.1 0.528 0.545 8 LNU106 14484.3 0.296 0.446 6 LNU114 25041.2 4.27 0.461 11 LNU155 14525.1 0.573 0.193 17 LNU114 25041.2 0.299 0.401 7 LNU155 14525.1 4.58 0.181 19 LNU155 14523.5 0.542 0.422 11 LNU114 25041.1 0.295 0.506 6 LNU155 14523.5 4.34 0.391 12 LNU213 24654.4 0.558 0.285 14 LNU114 25042.1 0.289 0.660 4 LNU213 24654.4 4.46 0.265 16 LNU218 24781.7 0.637 0.029 31 LNU213 24653.2 0.307 0.264 10 LNU218 24781.7 5.10 0.029 32 LNU218 24781.4 0.628 0.046 29 LNU213 24052.4 0.295 0.527 6 LNU218 24781.4 5.02 0.045 30 LNU218 24784.2 0.586 0.152 20 LNU218 24781.7 0.353 0.002 27 LNU218 24784.2 4.68 0.143 21 LNU23 25163.5 0.601 0.157 23 LNU218 24781.4 0.328 0.045 18 LNU23 25163.5 4.81 0.147 25 LNU23 25163.6 0.537 0.492 10 LNU218 24784.2 0.314 0.139 13 LNU23 25163.6 4.29 0.457 11 LNU28 25171.2 0.588 0.137 20 LNU218 24781.2 0.286 0.762 2 LNU28 25171.2 4.70 0.129 22 LNU28 25171.1 0.583 0.157 19 LNU23 25163.5 0.341 0.050 22 LNU28 25171.1 4.66 0.148 21 LNU28 25174.5 0.520 0.677 7 LNU23 25163.6 0.309 0.239 11 LNU28 25174.5 4.16 0.633 8 LNU4 25133.3 0.591 0.127 21 LNU28 25171.1 0.349 0.003 25 LNU4 25133.3 4.73 0.120 22 LNU4 25134.1 0.515 0.691 5 LNU28 25171.2 0.327 0.034 17 LNU4 25134.1 4.12 0.641 7 LNU40 24794.3 0.619 0.053 27 LNU28 25174.5 0.305 0.374 9 LNU40 24794.3 4.95 0.051 28 LNU40 24794.4 0.585 0.153 20 LNU28 25171.4 0.289 0.676 4 LNU40 24794.4 4.41 0.346 14 LNU46 14462.5 0.751 0.001 54 LNU4 25133.3 0.317 0.088 14 LNU46 14462.5 6.01 0.001 56 LNU46 14464.4 0.712 0.008 46 LNU4 25134.1 0.291 0.636 4 LNU46 14464.4 5.69 0.008 47 LNU46 14464.1 0.540 0.430 11 LNU4 25131.1 0.288 0.705 3 LNU46 14464.1 4.32 0.398 12 LNU46 14462.1 0.532 0.511 9 LNU40 24794.4 0.326 0.045 17 LNU46 14462.1 4.26 0.473 10 LNU46 14463.1 0.532 0.506 9 LNU40 24794.3 0.304 0.256 9 LNU46 14463.1 4.25 0.468 10 LNU48 24801.4 0.634 0.032 30 LNU46 14464.4 0.356 0.010 28 LNU48 24801.4 5.07 0.032 31 LNU48 24802.1 0.557 0.289 14 LNU46 14462.5 0.338 0.020 21 LNU48 24802.1 4.46 0.268 15 LNU48 24804.4 0.512 0.714 5 LNU46 14464.1 0.304 0.264 9 LNU48 24804.4 4.09 0.661 6 LNU63 24814.2 0.572 0.210 17 LNU46 14462.1 0.298 0.416 7 LNU63 24814.2 4.58 0.196 19 LNU63 24814.3 0.529 0.538 8 LNU46 14463.1 0.290 0.614 4 LNU63 24814.3 4.23 0.498 10 LNU63 24811.2 0.511 0.723 5 LNU48 24801.4 0.335 0.015 20 LNU63 24811.2 4.09 0.670 6 LNU7 25081.1 0.570 0.217 17 LNU48 24802.1 0.312 0.132 12 LNU7 25081.1 4.56 0.203 18 LNU7 25082.2 0.540 0.431 11 LNU63 24814.3 0.307 0.219 10 LNU7 25082.2 4.32 0.399 12 LNU8 25063.6 0.531 0.508 9 LNU63 24814.2 0.300 0.368 7 LNU8 25063.6 4.25 0.469 10 LNU8 25062.1 0.530 0.516 9 LNU63 24811.2 0.289 0.636 4 LNU8 25062.1 4.24 0.478 10 LNU8 25061.2 0.512 0.712 5 LNU7 25081.1 0.315 0.109 13 LNU8 25061.2 4.10 0.660 6 LNU8 25062.2 0.511 0.734 5 LNU7 25082.2 0.312 0.187 12 LNU8 25062.2 4.09 0.681 6 LNU94 24833.3 0.560 0.273 15 LNU8 25061.2 0.294 0.504 5 LNU94 24833.3 4.19 0.543 9 LNU96 25071.2 0.621 0.062 27 LNU8 25063.6 0.287 0.699 3 LNU96 25071.2 4.96 0.060 29 LNU96 25073.4 0.524 0.612 7 LNU94 24833.3 0.298 0.382 7 LNU96 25073.4 4.19 0.569 9 LNU96 25071.3 0.510 0.738 4 LNU96 25071.2 0.321 0.091 15 CONT. — 5.49 — 0 CONT. — 0.686 — 0 LNU96 25073.4 0.301 0.419 8 LNU113 25631.7 6.03 0.397 10 LNU113 25631.7 0.754 0.397 10 LNU96 25071.2 0.294 0.527 5 LNU113 25631.3 5.87 0.555 7 LNU113 25631.3 0.733 0.555 7 LNU96 25074.1 0.292 0.559 5 LNU113 25631.1 5.75 0.676 5 LNU113 25631.1 0.718 0.676 5 CONT. — 0.328 — 0 LNU140 14115.1 5.68 0.766 3 LNU140 14115.1 0.710 0.766 3 LNU113 25631.3 0.376 0.086 15 LNU148 25685.6 7.18 0.010 31 LNU148 25685.6 0.898 0.010 31 LNU113 25631.7 0.355 0.277 8 LNU148 25685.1 6.24 0.232 14 LNU148 25685.1 0.779 0.232 14 LNU113 25631.1 0.347 0.436 6 LNU148 25685.9 5.67 0.772 3 LNU148 25685.9 0.709 0.772 3 LNU120 25463.3 0.335 0.779 2 LNU5 14043.7 6.18 0.270 13 LNU5 14043.7 0.773 0.270 13 LNU132 14102.6 0.348 0.435 6 LNU74 25444.1 6.11 0.317 11 LNU74 25444.1 0.763 0.317 11 LNU148 25685.6 0.366 0.136 12 LNU98 25763.2 5.77 0.655 5 LNU98 25763.2 0.721 0.655 5 LNU148 25685.1 0.357 0.244 9 CONT. — 5.16 — 0 CONT. — 0.653 — 0 LNU148 25685.9 0.338 0.668 3 LNU113 25631.9 5.82 0.422 13 LNU113 25631.9 0.727 0.470 11 LNU287 24674.6 0.336 0.749 3 LNU148 25685.1 5.80 0.439 12 LNU148 25685.1 0.725 0.488 11 LNU5 14043.7 0.358 0.226 9 LNU72 24963.7 5.72 0.507 11 LNU72 24963.7 0.715 0.559 9 LNU68 14035.5 0.335 0.761 2 LNU72 24962.3 5.56 0.633 8 LNU72 24962.3 0.695 0.690 6 LNU74 25444.1 0.348 0.418 6 LNU98 25763.2 5.81 0.437 12 LNU98 25763.2 0.726 0.486 11 LNU74 25441.2 0.343 0.592 5 CONT. — 4.13 — 0 CONT. — 0.534 — 0 LNU74 25443.3 0.340 0.633 4 LNU117 25931.4 7.72 0.000 87 LNU117 25931.4 0.965 0.000 81 LNU74 25443.2 0.336 0.746 2 LNU117 25931.2 6.79 0.005 64 LNU117 25931.2 0.849 0.002 59 LNU87 24714.3 0.335 0.771 2 LNU117 25933.3 6.49 0.006 57 LNU117 25933.3 0.811 0.001 52 CONT. — 0.333 — 0 LNU117 25931.1 6.13 0.040 49 LNU117 25931.1 0.767 0.027 44 LNU113 25631.9 0.355 0.607 7 LNU117 25932.4 5.82 0.116 41 LNU117 25932.4 0.728 0.107 36 LNU148 25685.1 0.351 0.669 6 LNU122 25333.2 7.24 0.002 75 LNU122 25333.2 0.905 0.000 69 LNU74 25443.5 0.344 0.792 3 LNU122 25332.1 6.68 0.017 62 LNU122 25332.1 0.835 0.011 56 LNU98 25763.2 0.353 0.647 6 LNU122 25332.2 6.18 0.015 50 LNU122 25332.2 0.773 0.005 45 CONT. — 0.241 — 0 LNU122 25333.1 5.72 0.064 38 LNU122 25333.1 0.715 0.041 34 LNU117 25931.4 0.364 0.004 51 LNU122 25332.5 5.66 0.056 37 LNU122 25332.5 0.708 0.029 32 LNU117 25931.2 0.357 0.003 48 LNU125 25941.4 7.61 0.001 84 LNU125 25941.4 0.951 0.000 78 LNU117 25931.1 0.335 0.026 39 LNU125 25943.3 6.79 0.003 64 LNU125 25943.3 0.849 0.001 59 LNU117 25933.3 0.332 0.026 38 LNU125 25943.2 6.47 0.043 57 LNU125 25943.2 0.809 0.036 51 LNU117 25932.4 0.331 0.098 37 LNU125 25941.2 6.03 0.055 46 LNU125 25941.2 0.754 0.041 41 LNU122 25333.2 0.339 0.011 41 LNU125 25944.3 5.66 0.113 37 LNU125 25944.3 0.707 0.096 32 LNU122 25332.1 0.316 0.078 31 LNU138 14074.5 7.47 0.001 81 LNU138 14074.5 0.933 0.000 75 LNU122 25332.2 0.316 0.047 31 LNU138 14074.6 7.05 0.010 71 LNU138 14074.6 0.882 0.006 65 LNU122 25333.1 0.313 0.055 30 LNU138 14071.5 6.56 0.009 59 LNU138 14071.5 0.820 0.003 54 LNU122 25332.5 0.299 0.138 24 LNU138 14072.8 4.88 0.351 18 LNU138 14072.5 0.610 0.348 14 LNU125 25941.4 0.359 0.006 49 LNU138 14072.5 4.76 0.424 15 LNU138 14072.5 0.595 0.436 11 LNU125 25943.2 0.340 0.057 41 LNU180 24721.2 8.62 0.000 109 LNU180 24721.2 1.077 0.000 102 LNU125 25943.3 0.339 0.013 41 LNU180 24723.1 8.22 0.000 99 LNU180 24723.1 1.028 0.000 92 LNU125 25944.3 0.322 0.043 34 LNU180 24721.4 8.02 0.000 94 LNU180 24721.4 1.002 0.000 88 LNU125 25941.2 0.321 0.079 33 LNU180 24722.2 7.40 0.005 79 LNU180 24722.2 0.925 0.003 73 LNU138 14074.5 0.375 0.001 55 LNU180 24724.1 7.06 0.008 71 LNU180 24724.1 0.883 0.004 65 LNU138 14074.6 0.360 0.011 49 LNU220 25405.2 7.25 0.002 76 LNU220 25405.2 0.906 0.001 70 LNU138 14071.5 0.355 0.003 47 LNU220 25405.5 7.21 0.003 75 LNU220 25405.5 0.901 0.001 69 LNU138 14072.5 0.312 0.045 30 LNU220 25405.1 7.03 0.006 70 LNU220 25405.1 0.879 0.003 64 LNU138 14072.8 0.299 0.100 24 LNU220 25405.6 5.97 0.036 45 LNU220 25405.6 0.746 0.020 40 LNU180 24721.2 0.404 0.000 67 LNU220 25405.3 5.49 0.133 33 LNU220 25405.3 0.686 0.111 28 LNU180 24721.4 0.397 0.001 65 LNU230 25413.1 7.87 0.001 90 LNU230 25413.1 0.983 0.000 84 LNU180 24723.1 0.393 0.000 63 LNU230 25412.1 7.21 0.003 75 LNU230 25412.1 0.902 0.001 69 LNU180 24722.2 0.372 0.007 54 LNU230 25415.1 6.63 0.013 60 LNU230 25415.1 0.828 0.007 55 LNU180 24724.1 0.355 0.026 47 LNU230 25413.2 6.35 0.031 54 LNU230 25412.2 0.807 0.005 51 LNU220 25405.5 0.369 0.003 53 LNU230 25412.2 6.05 0.032 46 LNU230 25413.2 0.793 0.021 48 LNU220 25405.2 0.353 0.009 47 LNU234 25014.8 6.95 0.002 68 LNU234 25014.5 0.868 0.001 63 LNU220 25405.6 0.340 0.010 41 LNU234 25014.1 6.22 0.021 51 LNU234 25014.1 0.778 0.010 46 LNU220 25405.1 0.332 0.043 38 LNU234 25014.6 6.08 0.019 47 LNU234 25014.6 0.759 0.007 42 LNU220 25405.3 0.320 0.039 33 LNU234 25014.4 5.76 0.047 40 LNU234 25014.4 0.720 0.024 35 LNU230 25413.1 0.382 0.003 59 LNU234 25014.5 5.67 0.121 37 LNU234 25014.5 0.709 0.107 33 LNU230 25412.1 0.363 0.004 51 LNU25 14082.8 7.38 0.002 79 LNU25 14082.8 0.923 0.001 73 LNU230 25412.2 0.331 0.024 37 LNU25 14083.7 7.21 0.001 75 LNU25 14083.7 0.901 0.000 69 LNU230 25415.1 0.323 0.091 34 LNU25 14082.9 7.12 0.001 72 LNU25 14082.9 0.890 0.000 67 LNU230 25413.2 0.317 0.083 32 LNU25 14084.6 7.08 0.008 71 LNU25 14084.6 0.885 0.005 66 LNU234 25014.8 0.370 0.004 54 LNU25 14083.1 6.98 0.002 69 LNU25 14083.1 0.873 0.000 63 LNU234 25014.1 0.339 0.026 41 LNU254 25782.4 7.44 0.001 80 LNU254 25782.4 0.931 0.000 74 LNU234 25014.5 0.336 0.038 39 LNU254 25781.3 7.41 0.001 79 LNU254 25781.3 0.927 0.000 73 LNU234 25014.6 0.325 0.019 35 LNU254 25781.5 6.76 0.005 64 LNU254 25781.5 0.845 0.002 58 LNU234 25014.4 0.323 0.035 34 LNU254 25783.1 6.35 0.026 54 LNU254 25783.1 0.793 0.017 48 LNU25 14082.9 0.381 0.001 58 LNU254 25782.5 6.16 0.018 49 LNU254 25782.5 0.769 0.007 44 LNU25 14082.8 0.367 0.013 52 LNU263 25794.3 7.49 0.001 81 LNU263 25794.3 0.937 0.000 75 LNU25 14083.1 0.361 0.002 50 LNU263 25794.8 7.41 0.004 79 LNU263 25794.8 0.926 0.003 73 LNU25 14084.6 0.356 0.038 47 LNU263 25791.3 7.30 0.001 77 LNU263 25791.3 0.912 0.000 71 LNU25 14083.7 0.343 0.014 42 LNU263 25794.6 7.09 0.002 72 LNU263 25794.6 0.886 0.001 66 LNU254 25781.3 0.376 0.002 56 LNU263 25792.2 6.66 0.006 61 LNU263 25792.2 0.833 0.002 56 LNU254 25782.4 0.363 0.007 50 LNU267 25804.3 6.91 0.006 67 LNU267 25804.3 0.864 0.003 62 LNU254 25781.5 0.356 0.003 48 LNU267 25804.4 6.88 0.002 67 LNU267 25804.4 0.860 0.000 61 LNU254 25782.5 0.345 0.007 43 LNU267 25801.1 6.29 0.022 52 LNU267 25801.1 0.786 0.012 47 LNU254 25783.1 0.335 0.028 39 LNU267 25803.1 6.23 0.013 51 LNU267 25803.1 0.778 0.004 46 LNU263 25794.3 0.383 0.000 59 LNU267 25802.1 5.92 0.039 43 LNU267 25802.1 0.740 0.022 39 LNU263 25794.6 0.374 0.002 55 LNU271 25911.4 8.12 0.000 97 LNU271 25911.4 1.015 0.000 90 LNU263 25794.8 0.370 0.007 53 LNU271 25912.1 6.51 0.019 58 LNU271 25912.1 0.862 0.001 61 LNU263 25791.3 0.354 0.007 47 LNU271 25913.3 6.28 0.014 52 LNU271 25913.3 0.785 0.005 47 LNU263 25792.2 0.350 0.010 45 LNU271 25912.2 5.66 0.057 37 LNU271 25912.2 0.707 0.030 32 LNU267 25804.3 0.367 0.006 52 LNU271 25913.2 4.79 0.488 16 LNU271 25913.2 0.599 0.531 12 LNU267 25803.1 0.357 0.003 48 LNU278 25812.3 7.83 0.000 89 LNU278 25812.3 0.978 0.000 83 LNU267 25802.1 0.346 0.008 43 LNU278 25814.3 7.58 0.000 84 LNU278 25814.3 0.948 0.000 77 LNU267 25804.4 0.335 0.010 39 LNU278 25812.2 6.21 0.018 50 LNU278 25812.2 0.776 0.008 45 LNU267 25801.1 0.319 0.053 32 LNU278 25814.1 5.82 0.051 41 LNU278 25814.1 0.727 0.030 36 LNU271 25911.4 0.399 0.000 65 LNU278 25813.2 5.19 0.173 26 LNU278 25813.2 0.648 0.132 21 LNU271 25913.3 0.359 0.004 49 LNU36 25562.9 7.33 0.000 78 LNU36 25562.9 0.917 0.000 72 LNU271 25912.2 0.332 0.013 38 LNU36 25562.3 6.37 0.011 54 LNU36 25562.3 0.797 0.004 49 LNU271 25912.1 0.317 0.056 31 LNU36 25562.4 5.88 0.031 42 LNU36 25562.4 0.735 0.013 38 LNU271 25913.2 0.265 0.611 10 LNU36 25562.7 5.45 0.090 32 LNU36 25562.7 0.681 0.053 27 LNU278 25812.3 0.398 0.000 65 LNU36 25561.2 5.42 0.105 31 LNU36 25561.2 0.678 0.069 27 LNU278 25814.3 0.352 0.006 46 LNU43 14422.8 6.93 0.002 68 LNU43 14422.8 0.867 0.000 62 LNU278 25812.2 0.330 0.019 37 LNU43 14422.9 6.46 0.007 56 LNU43 14422.9 0.808 0.002 51 LNU278 25814.1 0.290 0.263 20 LNU43 14421.1 6.45 0.008 56 LNU43 14421.1 0.806 0.002 51 LNU278 25813.2 0.282 0.286 17 LNU43 14423.6 5.85 0.033 42 LNU43 14423.6 0.731 0.014 37 LNU36 25562.9 0.342 0.013 42 LNU43 14423.7 5.70 0.082 38 LNU43 14423.7 0.712 0.060 33 LNU36 25561.2 0.326 0.021 35 LNU45 25052.12 7.16 0.003 73 LNU45 25052.12 0.896 0.001 68 LNU36 25562.3 0.324 0.025 34 LNU45 25052.5 6.58 0.004 59 LNU45 25052.8 0.823 0.001 54 LNU36 25562.4 0.300 0.110 24 LNU45 25052.9 6.10 0.017 48 LNU45 25052.9 0.762 0.006 43 LNU36 25562.7 0.288 0.196 19 LNU45 25053.4 5.57 0.185 35 LNU45 25053.4 0.697 0.182 30 LNU43 14422.8 0.347 0.006 44 LNU45 25052.11 5.20 0.176 26 LNU45 25052.11 0.650 0.138 22 LNU43 14422.9 0.336 0.013 39 LNU67 25821.5 5.92 0.062 43 LNU67 25821.5 0.740 0.046 39 LNU43 14421.1 0.335 0.014 39 LNU67 25824.5 5.91 0.067 43 LNU67 25824.5 0.739 0.051 38 LNU43 14423.6 0.325 0.027 35 LNU67 25823.5 5.42 0.149 31 LNU67 25823.5 0.678 0.127 27 LNU43 14423.7 0.306 0.158 27 LNU67 25824.3 5.29 0.208 28 LNU67 25824.3 0.661 0.194 24 LNU45 25052.12 0.365 0.006 51 LNU67 25821.4 4.98 0.267 21 LNU67 25821.4 0.623 0.236 17 LNU45 25052.8 0.303 0.099 26 CONT. — 3.80 — 0 CONT. — 0.475 — 0 LNU45 25052.11 0.302 0.097 25 LNU100 14474.2 5.66 0.002 49 LNU100 14474.2 0.708 0.002 49 LNU45 25052.9 0.295 0.152 22 LNU100 14472.1 5.36 0.011 41 LNU100 14472.1 0.670 0.011 41 LNU45 25053.4 0.266 0.626 10 LNU100 14473.1 5.14 0.018 35 LNU100 14473.1 0.642 0.018 35 LNU67 25824.5 0.320 0.090 33 LNU100 14473.3 5.11 0.031 34 LNU100 14473.3 0.638 0.031 34 LNU67 25824.3 0.316 0.058 31 LNU100 14471.4 4.46 0.241 17 LNU100 14471.4 0.557 0.241 17 LNU67 25821.5 0.307 0.124 27 LNU104 25033.1 4.65 0.121 23 LNU104 25033.1 0.582 0.121 23 LNU67 25823.5 0.284 0.341 18 LNU104 25032.2 4.64 0.146 22 LNU104 25032.2 0.580 0.146 22 LNU67 25821.4 0.252 0.790 4 LNU104 25032.1 4.40 0.263 16 LNU104 25032.1 0.550 0.263 16 CONT. — 0.289 — 0 LNU104 25033.3 4.39 0.253 16 LNU104 25033.3 0.549 0.253 16 LNU100 14474.2 0.374 0.011 29 LNU104 25033.8 4.02 0.705 6 LNU104 25033.8 0.502 0.705 6 LNU100 14473.3 0.359 0.039 24 LNU106 14483.2 5.70 0.001 50 LNU106 14483.2 0.713 0.001 50 LNU100 14472.1 0.356 0.060 23 LNU106 14481.1 4.90 0.066 29 LNU106 14481.1 0.612 0.066 29 LNU100 14473.1 0.351 0.053 22 LNU106 14483.5 4.59 0.134 21 LNU106 14483.5 0.573 0.134 21 LNU100 14471.4 0.335 0.163 16 LNU106 14484.3 4.41 0.281 16 LNU106 14484.3 0.551 0.281 16 LNU104 25033.3 0.334 0.157 15 LNU114 25044.11 5.15 0.023 36 LNU114 25044.11 0.643 0.023 36 LNU104 25033.1 0.330 0.247 14 LNU114 25041.2 4.91 0.044 29 LNU114 25041.2 0.614 0.044 29 LNU104 25032.1 0.324 0.262 12 LNU114 25042.1 4.54 0.175 19 LNU114 25042.1 0.567 0.175 19 LNU104 25033.8 0.315 0.468 9 LNU114 25041.1 4.37 0.379 15 LNU114 25041.1 0.546 0.379 15 LNU104 25032.2 0.312 0.475 8 LNU114 25044.4 4.13 0.578 9 LNU114 25044.4 0.516 0.578 9 LNU106 14483.2 0.397 0.001 38 LNU117 25932.4 5.18 0.013 36 LNU117 25932.4 0.647 0.013 36 LNU106 14481.1 0.345 0.110 19 LNU117 25931.4 4.89 0.043 29 LNU117 25931.4 0.612 0.043 29 LNU106 14483.5 0.326 0.241 13 LNU117 25931.1 4.26 0.438 12 LNU117 25931.1 0.532 0.438 12 LNU106 14484.3 0.317 0.401 10 LNU117 25931.2 4.20 0.448 11 LNU117 25931.2 0.525 0.448 11 LNU114 25044.11 0.348 0.075 20 LNU155 14523.5 4.92 0.050 30 LNU155 14523.5 0.616 0.050 30 LNU114 25041.2 0.347 0.066 20 LNU155 14524.8 4.12 0.540 9 LNU155 14524.8 0.515 0.540 9 LNU114 25041.1 0.338 0.204 17 LNU180 24723.1 4.93 0.037 30 LNU180 24723.1 0.617 0.037 30 LNU114 25042.1 0.335 0.153 16 LNU180 24722.2 4.47 0.282 18 LNU180 24722.2 0.559 0.282 18 LNU117 25932.4 0.374 0.011 30 LNU218 24781.4 5.34 0.007 41 LNU218 24781.4 0.668 0.007 41 LNU117 25931.4 0.326 0.236 13 LNU218 24781.1 4.83 0.066 27 LNU218 24781.1 0.604 0.066 27 LNU117 25931.2 0.316 0.405 9 LNU218 24781.6 4.00 0.696 5 LNU218 24781.6 0.501 0.696 5 LNU117 25931.1 0.314 0.458 9 LNU218 24781.2 3.96 0.758 4 LNU218 24781.2 0.495 0.758 4 LNU155 14523.5 0.329 0.228 14 LNU254 25782.5 4.78 0.073 26 LNU254 25782.5 0.598 0.073 26 LNU155 14524.8 0.320 0.324 11 LNU4 25134.3 5.40 0.009 42 LNU4 25134.3 0.675 0.009 42 LNU180 24722.2 0.354 0.102 23 LNU4 25134.2 4.65 0.115 23 LNU4 25134.2 0.581 0.115 23 LNU180 24723.1 0.349 0.060 21 LNU4 25131.1 4.56 0.170 20 LNU4 25131.1 0.570 0.170 20 LNU180 24721.2 0.304 0.629 5 LNU4 25133.3 4.15 0.504 9 LNU4 25133.3 0.519 0.504 9 LNU218 24781.4 0.386 0.004 34 LNU40 24794.3 4.55 0.220 20 LNU40 24794.3 0.569 0.220 20 LNU218 24781.1 0.365 0.020 27 LNU40 24792.1 4.42 0.230 17 LNU40 24792.1 0.553 0.230 17 LNU218 24781.2 0.329 0.201 14 LNU40 24794.4 4.00 0.696 5 LNU40 24794.4 0.500 0.696 5 LNU218 24781.6 0.314 0.430 9 LNU46 14462.5 5.13 0.024 35 LNU46 14462.5 0.642 0.024 35 LNU254 25782.5 0.353 0.046 22 LNU46 14462.1 4.18 0.458 10 LNU46 14462.1 0.523 0.458 10 LNU4 25134.3 0.368 0.029 28 LNU46 14464.4 4.16 0.488 10 LNU46 14464.4 0.520 0.488 10 LNU4 25134.2 0.324 0.272 12 LNU48 24801.4 4.69 0.098 24 LNU48 24801.4 0.586 0.098 24 LNU4 25131.1 0.324 0.294 12 LNU48 24803.2 4.49 0.231 18 LNU48 24803.2 0.562 0.231 18 LNU4 25133.3 0.314 0.437 9 LNU63 24812.3 5.17 0.015 36 LNU48 24802.2 0.503 0.687 6 LNU40 24794.3 0.336 0.199 16 LNU63 24814.7 4.35 0.320 14 LNU63 24812.3 0.646 0.015 36 LNU40 24792.1 0.311 0.470 8 LNU7 25082.2 4.87 0.070 28 LNU63 24814.7 0.543 0.320 14 LNU40 24794.4 0.310 0.496 7 LNU7 25083.1 4.37 0.289 15 LNU7 25082.2 0.609 0.070 28 LNU46 14462.5 0.335 0.190 16 LNU7 25083. 4.21 0.443 11 LNU7 25083.1 0.546 0.289 15 LNU46 14462.1 0.323 0.265 12 LNU8 25063.6 5.22 0.013 37 LNU7 25083.3 0.526 0.443 11 LNU46 14464.4 0.312 0.454 8 LNU8 25061.2 4.50 0.170 19 LNU8 25063.6 0.652 0.013 37 LNU48 24803.2 0.337 0.175 17 LNU94 24833.3 4.45 0.240 17 LNU8 25061.2 0.563 0.179 19 LNU48 24801.4 0.334 0.166 16 CONT. — 5.26 — 0 LNU94 24833.3 0.556 0.240 17 LNU48 24802.2 0.310 0.515 7 LNU122 25332.1 6.26 0.154 19 CONT. — 0.658 — 0 LNU48 24804.4 0.300 0.715 4 LNU122 25332.2 6.17 0.190 17 LNU122 25332.1 0.782 0.154 19 LNU63 24812.3 0.356 0.041 23 LNU122 25332.5 5.78 0.455 10 LNU122 25332.2 0.771 0.190 17 LNU63 24814.7 0.327 0.239 13 LNU125 25943.2 5.69 0.530 8 LNU122 25332.5 0.723 0.455 10 LNU63 24814.2 0.310 0.494 7 LNU125 25941.4 5.58 0.64 6 LNU125 25943.2 0.711 0.530 8 LNU7 25082.2 0.341 0.128 18 LNU125 25944.1 5.44 0.797 3 LNU125 25941.4 0.697 0.643 6 LNU7 25083.1 0.339 0.114 17 LNU138 14074.5 5.71 0.514 8 LNU125 25944.1 0.681 0.797 3 LNU8 25063.6 0.354 0.046 23 LNU157 24982.1 5.62 0.607 7 LNU138 14074.5 0.714 0.514 8 LNU8 25061.2 0.324 0.254 12 LNU178 14614.5 6.17 0.189 17 LNU157 24982.1 0.703 0.607 7 CONT. — 0.352 — 0 LNU178 14611.5 5.80 0.430 10 LNU178 14614.5 0.771 0.189 17 LNU10 25123.5 0.379 0.378 8 LNU178 14612.1 5.63 0.595 7 LNU178 14611.5 0.725 0.430 10 LNU122 25332.2 0.399 0.125 13 LNU178 14611.4 5.56 0.664 6 LNU178 14612.1 0.704 0.595 7 LNU122 25332.1 0.394 0.177 12 LNU220 25405.6 5.86 0.398 11 LNU178 14611.4 0.695 0.664 6 LNU122 25332.5 0.388 0.241 10 LNU220 25405.5 5.83 0.409 11 LNU220 25405.6 0.732 0.398 11 LNU125 25944.1 0.370 0.592 5 LNU220 25405.1 5.79 0.438 10 LNU220 25405.5 0.729 0.409 11 LNU125 25943.2 0.367 0.611 4 LNU220 25405.2 5.59 0.633 6 LNU220 25405.1 0.723 0.438 10 LNU125 25941.2 0.367 0.639 4 LNU234 25014.4 5.62 0.621 7 LNU220 25405.2 0.699 0.633 6 LNU138 14074.5 0.393 0.180 12 LNU234 25014.6 5.50 0.728 5 LNU234 25014.4 0.703 0.621 7 LNU138 14071.5 0.376 0.424 7 LNU236 25424.2 6.84 0.028 30 LNU234 25014.6 0.688 0.728 5 LNU138 14074.6 0.371 0.526 5 LNU236 25422.4 5.91 0.336 12 LNU236 25424.2 0.855 0.028 30 LNU157 24982.1 0.399 0.137 13 LNU236 25425.4 5.82 0.420 11 LNU236 25422.4 0.739 0.336 12 LNU157 24983.3 0.365 0.675 4 LNU236 25423.3 5.76 0.479 9 LNU236 25425.4 0.728 0.420 11 LNU178 14611.5 0.382 0.336 8 LNU24 24974.2 5.55 0.672 5 LNU236 25423.3 0.720 0.479 9 LNU178 14614.5 0.381 0.325 8 LNU24 24972.1 5.45 0.786 4 LNU24 24974.2 0.694 0.672 5 LNU178 14611.1 0.370 0.552 5 LNU25 14082.8 6.62 0.055 26 LNU24 24972.1 0.681 0.786 4 LNU178 14611.4 0.366 0.648 4 LNU25 14082.9 5.75 0.484 9 LNU25 14082.8 0.827 0.055 26 LNU178 14612.1 0.363 0.717 3 LNU25 14084.6 5.55 0.670 6 LNU25 14082.9 0.719 0.484 9 LNU220 25405.2 0.382 0.336 8 LNU271 25911.4 5.93 0.358 13 LNU25 14084.6 0.694 0.670 6 LNU220 25405.5 0.376 0.427 7 LNU278 25814.1 5.78 0.448 10 LNU271 25911.4 0.741 0.358 13 LNU220 25405.6 0.367 0.635 4 LNU278 25814.3 5.50 0.720 5 LNU278 25814.1 0.722 0.448 10 LNU234 25014.6 0.368 0.595 5 LNU278 25812.2 5.47 0.754 4 LNU278 25814.3 0.688 0.720 5 LNU236 25424.2 0.423 0.025 20 LNU43 14423.7 5.68 0.545 8 LNU278 25812.2 0.684 0.754 4 LNU236 25423.3 0.379 0.418 8 LNU43 14422.9 5.46 0.777 4 LNU43 14423.7 0.709 0.545 8 LNU236 25422.4 0.366 0.629 4 LNU45 25052.12 7.19 0.008 36 LNU43 14422.9 0.683 0.777 4 LNU24 24972.1 0.372 0.522 6 LNU45 25053.4 6.71 0.048 27 LNU45 25052.12 0.898 0.008 36 LNU24 24971.2 0.365 0.689 4 LNU45 25052.11 5.94 0.317 13 LNU45 25053.4 0.839 0.048 27 LNU24 24974.2 0.364 0.696 3 LNU45 25052.9 5.75 0.471 9 LNU45 25052.11 0.742 0.317 13 LNU25 14082.8 0.395 0.154 12 LNU67 25824.3 6.41 0.104 22 LNU45 25052.9 0.719 0.471 9 LNU25 14082.9 0.393 0.184 12 LNU67 25824.5 5.89 0.354 12 LNU67 25824.3 0.801 0.104 22 LNU271 25911.4 0.388 0.243 10 LNU67 25821.4 5.70 0.521 8 LNU67 25824.5 0.736 0.354 12 LNU271 25912.1 0.362 0.743 3 LNU9 25001.1 6.13 0.201 16 LNU67 25821.4 0.713 0.521 8 LNU278 25813.2 0.382 0.340 8 LNU9 25001.7 6.03 0.271 15 LNU9 25001.1 0.767 0.201 16 LNU43 14422.9 0.379 0.417 8 LNU9 25003.1 5.56 0.670 6 LNU9 25001.7 0.754 0.271 15 LNU43 14423.7 0.377 0.421 7 CONT. — 5.11 — 0 LNU9 25003.1 0.695 0.670 6 LNU43 14423.6 0.365 0.680 4 LNU10 25123.6 6.24 0.253 22 CONT. — 0.638 — 0 LNU45 25052.12 0.407 0.076 16 LNU157 24982.8 6.83 0.09 34 LNU10 25123.6 0.779 0.253 22 LNU45 25053.4 0.397 0.161 13 LNU157 24982.4 5.78 0.506 13 LNU157 24982.8 0.853 0.093 34 LNU45 25052.9 0.368 0.599 4 LNU157 24983.3 5.44 0.736 7 LNU157 24982.4 0.723 0.506 13 LNU67 25824.3 0.395 0.165 12 LNU168 24751.2 5.47 0.732 7 LNU157 24983.3 0.680 0.736 7 LNU67 25824.5 0.393 0.173 12 LNU173 25451.1 6.15 0.322 20 LNU168 24751.2 0.683 0.732 7 LNU67 25821.4 0.368 0.597 5 LNU178 14611.4 7.38 0.047 45 LNU173 25451.1 0.768 0.322 20 LNU67 25821.5 0.364 0.712 3 LNU178 14611.5 6.73 0.122 32 LNU178 14611.4 0.923 0.047 45 LNU9 25001.7 0.379 0.381 8 LNU178 14611.1 6.59 0.187 29 LNU178 14611.5 0.842 0.122 32 LNU9 25001.2 0.378 0.396 7 LNU184 25393.2 6.42 0.202 26 LNU178 14011.1 0.823 0.187 29 LNU9 25003.1 0.370 0.566 5 LNU184 25393.3 6.25 0.281 22 LNU184 25393.2 0.803 0.202 26 LNU9 25001.1 0.368 0.580 5 LNU184 25393.1 6.04 0.411 18 LNU184 25393.3 0.782 0.281 22 CONT. — 0.307 — 0 LNU184 25395.1 5.98 0.419 17 LNU184 25393.1 0.755 0.411 18 LNU157 24982.8 0.372 0.169 21 LNU230 25413.1 6.82 0.101 34 LNU184 25395.1 0.747 0.419 17 LNU157 24982.4 0.354 0.335 16 LNU230 25413.2 6.73 0.124 32 LNU230 25413.1 0.852 0.101 34 LNU157 24983.3 0.319 0.797 4 LNU230 25412.1 6.22 0.275 22 LNU230 25413.2 0.841 0.124 32 LNU168 24751.2 0.346 0.435 13 LNU230 25412.2 6.09 0.339 19 LNU230 25412.1 0.778 0.275 22 LNU173 25451.1 0.399 0.076 30 LNU230 25415.1 6.04 0.370 18 LNU230 25412.2 0.761 0.339 19 LNU173 25451.11 0.337 0.519 10 LNU236 25425.4 7.78 0.014 52 LNU230 25415.1 0.755 0.370 18 LNU173 25451.2 0.335 0.563 9 LNU236 25423.3 6.50 0.189 27 LNU236 25425.4 0.973 0.014 52 LNU178 14611.4 0.400 0.074 30 LNU236 25422.4 5.94 0.416 16 LNU236 25423.3 0.813 0.189 27 LNU178 14611.5 0.379 0.143 24 LNU236 25424.2 5.93 0.419 16 LNU236 25422.4 0.743 0.416 16 LNU178 14611.1 0.353 0.368 15 LNU24 24974.2 7.22 0.048 41 LNU236 25424.2 0.741 0.419 16 LNU184 25393.3 0.368 0.232 20 LNU24 24971.3 6.02 0.366 18 LNU24 24974.2 0.903 0.048 41 LNU184 25393.2 0.358 0.291 17 LNU263 25791.3 6.66 0.142 30 LNU24 24971.3 0.753 0.366 18 LNU184 25395.1 0.354 0.364 15 LNU263 25794.3 6.36 0.229 25 LNU263 25791.3 0.832 0.142 30 LNU184 25393.1 0.344 0.492 12 LNU263 25794.8 6.23 0.272 22 LNU263 25794.3 0.795 0.229 25 LNU184 25394.3 0.325 0.701 6 LNU263 25792.2 5.56 0.649 9 LNU263 25794.5 0.779 0.272 22 LNU20 24933.4 0.348 0.400 13 LNU276 25433.1 6.40 0.218 25 LNU263 25792.2 0.695 0.649 9 LNU230 25413.2 0.382 0.133 25 LNU276 25431.1 6.37 0.226 25 LNU276 25433.1 0.800 0.218 25 LNU230 25413.1 0.373 0.175 22 LNU276 25433.3 6.01 0.361 18 LNU276 25431.1 0.796 0.226 25 LNU230 25412.1 0.352 0.348 15 LNU279 25484.3 6.77 0.111 33 LNU276 25433.3 0.752 0.361 18 LNU230 25415.1 0.340 0.486 11 LNU279 25481.3 6.62 0.165 30 LNU279 25484.3 0.846 0.111 33 LNU230 25412.2 0.327 0.684 7 LNU279 25481.5 6.32 0.245 24 LNU279 25481.3 0.827 0.165 30 LNU236 25425.4 0.426 0.018 39 LNU279 25481.2 6.07 0.400 19 LNU279 25481.5 0.790 0.245 24 LNU236 25423.3 0.352 0.365 15 LNU279 25481.4 6.07 0.356 19 LNU279 25481.2 0.759 0.400 19 LNU236 25424.2 0.352 0.351 15 LNU36 25562.3 6.64 0.161 30 LNU279 25481.4 0.759 0.356 19 LNU236 25422.4 0.325 0.705 6 LNU36 25562.7 6.54 0.219 28 LNU36 25562.3 0.830 0.161 30 LNU24 24974.2 0.401 0.057 31 LNU36 25561.2 6.18 0.307 21 LNU36 25562.7 0.817 0.219 28 LNU24 24971.3 0.361 0.263 18 LNU56 24694.1 6.66 0.177 31 LNU36 25561.2 0.772 0.307 21 LNU24 24971.4 0.348 0.467 14 LNU56 24693.1 6.41 0.228 25 LNU56 24694.1 0.833 0.177 31 LNU24 24971.2 0.323 0.729 5 LNU56 24691.2 6.26 0.267 23 LNU56 24693.1 0.801 0.228 25 LNU263 25791.3 0.362 0.271 18 LNU56 24694.2 5.66 0.598 11 LNU56 24691.2 0.783 0.267 23 LNU263 25794.8 0.361 0.260 18 LNU73 25755.1 7.76 0.015 52 LNU56 24694.2 0.707 0.598 11 LNU263 25794.3 0.354 0.328 15 LNU73 25751.1 6.71 0.120 31 LNU73 25755.1 0.970 0.015 52 LNU263 25794.6 0.341 0.506 11 LNU73 25751.9 6.57 0.163 29 LNU73 25751.1 0.839 0.120 31 LNU276 25433.1 0.382 0.135 25 LNU73 25751.8 6.32 0.271 24 LNU73 25751.9 0.822 0.163 29 LNU276 25431.1 0.374 0.174 22 LNU73 25754.2 6.25 0.291 22 LNU73 25751.8 0.790 0.271 24 LNU276 25433.3 0.346 0.409 13 LNU9 25001.7 6.80 0.115 33 LNU73 25754.2 0.782 0.291 22 LNU276 25433.2 0.338 0.534 10 LNU9 25001.1 6.51 0.177 27 LNU9 25001.7 0.851 0.115 33 LNU279 25481.3 0.372 0.202 21 LNU9 25001.2 6.05 0.356 18 LNU9 25001.1 0.813 0.177 27 LNU279 25484.3 0.367 0.215 20 CONT. — 3.57 — 0 LNU9 25001.2 0.756 0.356 18 LNU279 25481.4 0.355 0.331 16 LNU131 14005.5 7.37 0.000 106 CONT. — 0.451 — 0 LNU279 25481.2 0.346 0.475 13 LNU131 14005.2 5.32 0.050 49 LNU131 14005.5 0.921 0.000 104 LNU279 25481.5 0.341 0.485 11 LNU131 14002.15 4.88 0.135 36 LNU131 14005.2 0.665 0.059 47 LNU36 25562.3 0.393 0.090 28 LNU135 26204.2 7.67 0.000 115 LNU131 14002.15 0.609 0.154 35 LNU36 25561.2 0.371 0.195 21 LNU135 26203.6 5.27 0.052 48 LNU135 26204.2 0.959 0.000 113 LNU36 25562.7 0.361 0.323 18 LNU135 26203.4 5.22 0.074 46 LNU135 26203.6 0.659 0.061 46 LNU36 25562.4 0.331 0.618 8 LNU135 26203.1 4.95 0.109 39 LNU135 26203.4 0.653 0.085 45 LNU36 25562.9 0.321 0.763 5 LNU135 26203.3 4.18 0.494 17 LNU135 26203.1 0.619 0.126 37 LNU53 25674.1 0.328 0.660 7 LNU161 14553.5 5.35 0.060 50 LNU135 26203.3 0.522 0.528 16 LNU53 25674.3 0.324 0.716 6 LNU161 14553.6 4.33 0.372 21 LNU161 14553.5 0.669 0.069 48 LNU53 25674.6 0.322 0.759 5 LNU173 25451.2 4.03 0.583 13 LNU161 14553.6 0.541 0.404 20 LNU56 24694.1 0.381 0.171 24 LNU173 25451.5 3.89 0.709 9 LNU173 25451.2 0.504 0.620 12 LNU56 24693.1 0.372 0.204 21 LNU181 25771.2 5.43 0.036 52 LNU173 25451.5 0.486 0.746 8 LNU56 24691.2 0.368 0.220 20 LNU181 25771.11 4.74 0.176 33 LNU181 25771.2 0.679 0.044 51 LNU56 24694.2 0.343 0.477 12 LNU181 25771.6 4.74 0.171 33 LNU181 25771.11 0.593 0.198 31 LNU73 25755.1 0.405 0.051 32 LNU181 25774.1 4.36 0.350 22 LNU181 25771.6 0.593 0.194 31 LNU73 25751.1 0.387 0.103 26 LNU181 25771.8 3.81 0.783 7 LNU181 25774.1 0.545 0.382 21 LNU73 25751.8 0.379 0.165 24 LNU184 25395.1 6.17 0.006 73 LNU184 25395.1 0.771 0.007 71 LNU73 25754.2 0.378 0.171 23 LNU184 25394.3 6.00 0.010 68 LNU184 25394.3 0.750 0.012 66 LNU73 25751.9 0.377 0.145 23 LNU184 25394.1 5.43 0.040 52 LNU184 25394.1 0.678 0.047 50 LNU9 25001.1 0.374 0.163 22 LNU184 25393.3 5.24 0.057 47 LNU184 25393.3 0.655 0.068 45 LNU9 25001.7 0.370 0.207 21 LNU184 25393.2 4.23 0.436 18 LNU184 25393.2 0.529 0.470 17 LNU9 25001.2 0.350 0.362 14 LNU184 25393.1 4.19 0.472 17 LNU184 25393.1 0.524 0.506 16 LNU9 25001.3 0.326 0.687 6 LNU224 25871.3 5.98 0.008 67 LNU224 25871.3 0.747 0.010 66 LNU9 25003.1 0.325 0.718 6 LNU224 25874.1 5.87 0.010 64 LNU224 25874.1 0.734 0.013 63 CONT. — 0.287 — 0 LNU224 25872.2 5.35 0.047 50 LNU224 25872.2 0.669 0.056 48 LNU131 14005.5 0.396 0.020 38 LNU224 25874.4 4.53 0.266 27 LNU224 25872.3 0.601 0.174 33 LNU131 14005.2 0.353 0.165 23 LNU224 25872.3 4.51 0.278 26 LNU224 25874.4 0.567 0.294 26 LNU131 14002.15 0.328 0.376 14 LNU246 25743.2 5.97 0.014 67 LNU246 25743.2 0.747 0.017 66 LNU135 26204.2 0.437 0.003 52 LNU246 25743.1 5.65 0.024 58 LNU246 25743.1 0.707 0.029 57 LNU135 26203.4 0.343 0.244 20 LNU246 25744.2 5.49 0.039 54 LNU246 25744.2 0.687 0.046 52 LNU135 26203.6 0.336 0.290 17 LNU246 25744.4 5.08 0.111 42 LNU246 25744.4 0.635 0.126 41 LNU135 26203.1 0.315 0.540 10 LNU246 25744.3 4.48 0.282 26 LNU246 25744.3 0.561 0.311 24 LNU135 26203.3 0.310 0.641 8 LNU250 25592.2 5.37 0.043 50 LNU250 25592.2 0.672 0.051 49 LNU161 14553.5 0.320 0.500 11 LNU250 25592.1 4.28 0.412 20 LNU250 25592.1 0.535 0.445 19 LNU181 25771.2 0.339 0.265 18 LNU250 25591.1 4.28 0.410 20 LNU250 25591.1 0.535 0.444 18 LNU181 25771.6 0.327 0.380 14 LNU260 26404.8 4.71 0.191 32 LNU260 26404.8 0.589 0.213 31 LNU181 25771.11 0.318 0.505 11 LNU260 26404.7 4.63 0.238 30 LNU260 26404.7 0.579 0.263 28 LNU181 25774.1 0.309 0.638 7 LNU260 26404.1 4.46 0.311 25 LNU260 26404.1 0.558 0.340 24 LNU181 25771.8 0.299 0.795 4 LNU260 26403.1 3.81 0.777 7 LNU276 25433.6 0.602 0.175 33 LNU184 25395.1 0.377 0.063 31 LNU276 25433.6 4.82 0.154 35 LNU276 25431.1 0.542 0.404 20 LNU184 25394.3 0.362 0.119 26 LNU276 25431.1 4.33 0.371 21 LNU276 25433.5 0.532 0.459 18 LNU184 25394.1 0.333 0.318 16 LNU276 25433.5 4.26 0.426 19 LNU279 25484.3 0.667 0.061 48 LNU184 25393.3 0.330 0.355 15 LNU279 25484.3 5.34 0.052 49 LNU279 25481.3 0.604 0.202 34 LNU184 25393.1 0.304 0.714 6 LNU279 25481.3 4.83 0.182 35 LNU279 25481.5 0.568 0.292 26 LNU184 25393.2 0.303 0.726 6 LNU279 25481.5 4.54 0.265 27 LNU279 25481.4 0.525 0.497 16 LNU224 25871.3 0.367 0.086 28 LNU279 25481.4 4.20 0.463 18 LNU3 26122.2 0.614 0.157 36 LNU224 25872.2 0.364 0.104 27 LNU3 26122.2 4.91 0.139 37 LNU33 25553.3 0.686 0.040 52 LNU224 25874.1 0.355 0.138 24 LNU33 25553.3 5.48 0.034 54 LNU33 25553.2 0.615 0.142 36 LNU224 25872.3 0.315 0.548 10 LNU33 25552.2 4.78 0.197 34 LNU33 25552.2 0.598 0.218 32 LNU246 25743.2 0.369 0.100 29 LNU33 25553.2 4.57 0.246 28 LNU33 25553.1 0.522 0.527 16 LNU246 25743.1 0.354 0.164 23 LNU33 25553.1 4.18 0.493 17 LNU53 25674.6 0.546 0.383 21 LNU246 25744.2 0.347 0.216 21 LNU53 25674.6 4.37 0.352 22 LNU73 25751.8 0.521 0.539 16 LNU246 25744.4 0.344 0.256 20 LNU73 25751.8 4.17 0.506 17 CONT. — 0.809 — 0 LNU246 25744.3 0.313 0.570 9 CONT. — 6.47 — 0 LNU119 26144.2. 0.861 0.646 6 LNU250 25592.2 0.359 0.121 25 LNU119 26144.2. 6.89 0.646 6 LNU130 24912.7. 0.932 0.319 15 LNU250 25592.1 0.308 0.649 7 LNU130 24912.7. 7.45 0.319 15 LNU130 24913.6. 0.926 0.303 14 LNU250 25591.1 0.301 0.772 5 LNU130 24913.6. 7.41 0.303 14 LNU130 24914.5. 0.893 0.475 10 LNU260 26404.7 0.321 0.485 12 LNU130 24914.5. 7.14 0.475 10 LNU130 24911.7. 0.860 0.661 6 LNU260 26404.8 0.316 0.529 10 LNU130 24911.7. 6.88 0.661 6 LNU136 14511.10. 1.025 0.060 27 LNU276 25433.6 0.332 0.330 16 LNU136 14511.10 8.20 0.060 27 LNU136 14515.5. 0.969 0.180 20 LNU276 25431.1 0.302 0.738 5 LNU136 14515.5. 7.75 0.180 20 LNU142 27541.1. 0.946 0.231 17 LNU279 25481.3 0.346 0.238 21 LNU142 27541.1. 7.57 0.231 17 LNU149 26175.3. 0.901 0.415 11 LNU279 25484.3 0.345 0.234 20 LNU149 26175.3. 6.73 0.773 4 LNU15 14123.13. 0.904 0.411 12 LNU279 25481.5 0.323 0.444 12 LNU15 14123.13. 7.23 0.411 12 LNU15 14123.11. 0.901 0.455 11 LNU279 25481.4 0.310 0.615 8 LNU15 14123.11 6.81 0.737 5 LNU183 26474.2. 1.021 0.089 26 LNU3 26122.2 0.336 0.309 17 LNU185 26474.2. 8.17 0.089 26 LNU185 26475.1. 0.982 0.132 21 LNU33 25553.3 0.364 0.103 27 LNU185 26475.1 7.86 0.132 21 LNU185 26474.1. 0.893 0.487 10 LNU33 25552.2 0.339 0.288 18 LNU185 26474.1. 7.14 0.487 10 LNU212 25833.2. 1.095 0.020 35 LNU33 25553.2 0.329 0.365 14 LNU212 25833.2. 8.76 0.020 35 LNU212 25834.4. 1.035 0.067 28 LNU33 25553.1 0.320 0.487 11 LNU212 25834.4. 8.28 0.067 28 LNU212 25834.5. 0.941 0.254 16 LNU53 25674.6 0.311 0.601 8 LNU212 25834.3. 7.53 0.254 16 LNU212 25832.1. 0.863 0.630 7 LNU56 24694.2 0.303 0.733 5 LNU212 25832.1. 6.91 0.630 7 LNU216 25985.4. 1.045 0.062 29 LNU73 25751.8 0.329 0.404 14 LNU216 25985.4. 8.36 0.062 29 LNU216 25984.1. 1.010 0.104 25 CONT. — 0.359 — 0 LNU216 25984.1. 8.08 0.104 25 LNU216 25982.1. 1.005 0.090 24 LNU119 26144.2. 0.399 0.196 11 LNU216 25982.1. 8.04 0.090 24 LNU216 25984.6. 0.878 0.537 9 LNU130 24912.7. 0.417 0.098 16 LNU216 25984.6. 7.02 0.537 9 LNU228 26224.7. 0.989 0.123 22 LNU130 24911.7. 0.407 0.136 13 LNU228 26224.7. 7.91 0.123 22 LNU228 26222.4. 0.907 0.385 12 LNU130 24914.5. 0.398 0.243 11 LNU228 26222.4. 7.26 0.385 12 LNU229 26112.3. 0.956 0.208 18 LNU130 24913.6. 0.378 0.541 5 LNU229 26112.3. 7.65 0.208 18 LNU253 26241.1. 0.935 0.281 16 LNU136 14511.10. 0.415 0.062 15 LNU253 26241.1. 7.48 0.281 16 LNU280 26162.1. 0.941 0.274 16 LNU136 14515.5. 0.388 0.397 8 LNU280 26162.1. 7.53 0.274 16 LNU55 26015.1. 0.911 0.389 13 LNU136 14514.8. 0.378 0.553 5 LNU55 26015.1. 7.28 0.389 13 LNU81 26034.2. 0.891 0.476 10 LNU136 14515.1 0.369 0.761 3 LNU81 26034.2. 7.13 0.476 10 LNU81 26031.9. 0.891 0.493 10 LNU142 27541.1. 0.391 0.310 9 LNU81 26031.9. 7.13 0.49 10 CONT. — 0.822 — 0 LNU149 26175.3. 0.393 0.257 9 CONT. — 6.58 — 0 LNU119 26141.1. 1.016 0.363 24 LNU149 26175.1. 0.373 0.647 4 LNU119 26141.1. 8.13 0.363 24 LNU119 26142.5. 0.876 0.777 7 LNU15 14123.13. 0.399 0.197 11 LNU119 26142.5. 7.01 0.777 7 LNU130 24913.5. 0.946 0.514 15 LNU15 14123.11. 0.387 0.443 8 LNU130 24913.5. 7.57 0.514 15 LNU130 24914.5. 0.903 0.668 10 LNU15 14122.9. 0.374 0.645 4 LNU130 24914.5. 7.22 0.668 10 LNU136 14515.1. 0.892 0.711 8 LNU185 26474.2. 0.414 0.133 15 LNU136 14515.1. 7.13 0.711 8 LNU142 27546.2. 0.902 0.680 10 LNU185 26475.1. 0.399 0.193 11 LNU142 27546.2. 7.22 0.680 10 LNU142 27545.1. 0.876 0.780 7 LNU185 26474.1. 0.399 0.242 11 LNU142 27545.1. 7.01 0.780 7 LNU15 14124.12. 0.984 0.405 20 LNU212 25833.2. 0.436 0.019 21 LNU15 14124.12. 7.87 0.405 20 LNU15 14122.8. 0.942 0.541 15 LNU212 25834.4. 0.435 0.026 21 LNU15 14122.8. 7.54 0.541 15 LNU15 14123.13. 0.904 0.666 10 LNU212 25834.5. 0.431 0.028 20 LNU15 14123.13. 7.23 0.666 10 LNU185 26474.1. 1.074 0.194 31 LNU212 25834.1. 0.404 0.167 13 LNU185 26474.1. 8.59 0.194 31 LNU212 25834.4. 1.045 0.255 27 LNU212 25832.1. 0.391 0.298 9 LNU212 25834.4. 8.36 0.255 27 LNU212 25834.5. 0.924 0.596 12 LNU216 25984.1 0.448 0.011 25 LNU212 25834.5. 7.39 0.596 12 LNU216 25985.4. 1.096 0.186 33 LNU216 25982.1. 0.445 0.005 24 LNU216 25985.4. 8.77 0.186 33 LNU216 25982.1. 0.951 0.499 16 LNU216 25985.4. 0.425 0.060 18 LNU216 25982.1. 7.61 0.499 16 LNU216 25984.6. 0.925 0.610 12 LNU216 25984.6. 0.400 0.175 11 LNU216 25984.6. 7.40 0.610 12 LNU228 26225.2. 1.099 0.161 34 LNU228 26222.4. 0.401 0.170 12 LNU228 26225.2. 8.79 0.161 34 LNU228 26224.7. 1.018 0.337 24 LNU228 26224.7. 0.385 0.414 7 LNU228 26224.6. 7.80 0.434 19 LNU228 26224.6. 0.974 0.434 19 LNU228 26224.6. 0.383 0.450 7 LNU228 26222.4. 7.58 0.509 15 LNU228 26222.4. 0.948 0.509 15 LNU228 26222.1. 0.379 0.588 5 LNU228 26222.1. 7.54 0.528 15 LNU228 26222.1. 0.943 0.528 15 LNU229 26112.3. 0.419 0.057 17 LNU229 26111.7. 8.25 0.318 25 LNU229 26111.7. 1.031 0.318 25 LNU229 26112.6. 0.371 0.710 3 LNU229 26111.5. 8.05 0.348 22 LNU229 26111.5. 1.006 0.348 22 LNU253 26241.1. 0.402 0.172 12 LNU229 26112.4. 7.87 0.406 20 LNU229 26112.4. 0.984 0.406 20 LNU253 26245.1. 0.385 0.402 7 LNU229 26112.3. 7.83 0.423 19 LNU229 26112.3. 0.978 0.423 19 LNU274 26264.2. 0.383 0.481 7 LNU241 26232.4. 7.72 0.458 17 LNU241 26232.4. 0.965 0.458 17 LNU274 26263.2. 0.372 0.661 4 LNU241 26233.3. 7.50 0.574 14 LNU241 26233.3. 0.938 0.574 14 LNU280 26162.1. 0.404 0.172 13 LNU241 26234.1. 7.10 0.729 8 LNU241 26234.1. 0.888 0.729 8 LNU280 26164.4. 0.367 0.797 2 LNU253 26242.1. 7.19 0.695 9 LNU253 26242.1. 0.899 0.695 9 LNU55 26015.1. 0.382 0.493 6 LNU274 26265.1. 7.39 0.618 12 LNU274 26265.1. 0.923 0.618 12 LNU81 26031.9. 0.378 0.557 5 LNU274 26262.2. 7.31 0.646 11 LNU274 26262.2. 0.913 0.646 11 LNU81 26034.3. 0.373 0.646 4 LNU280 26162.1. 7.93 0.386 21 LNU280 26162.1. 0.992 0.386 21 CONT. — 0.401 — 0 LNU55 26013.3. 7.44 0.609 13 LNU280 26164.4. 0.904 0.662 10 LNU119 26141.1. 0.431 0.688 8 LNU55 26015.1. 7.37 0.602 12 LNU55 26013.3. 0.930 0.609 13 LNU130 24912.7. 0.420 0.792 5 LNU55 26013.4. 7.34 0.613 12 LNU55 26015.1. 0.922 0.602 12 LNU15 14122.8. 0.431 0.661 8 LNU81 26031.10. 7.95 0.440 21 LNU55 26013.4. 0.917 0.613 12 LNU15 14124.12. 0.425 0.727 6 LNU81 26031.2. 7.50 0.541 14 LNU81 26031.10. 0.994 0.440 21 LNU185 26474.1. 0.469 0.311 17 LNU81 26031.2. 0.937 0.541 14 LNU212 25834.4. 0.443 0.521 11 LNU216 25985.4. 0.437 0.596 9 LNU216 25982.1. 0.424 0.725 6 LNU228 26224.7. 0.460 0.397 15 LNU228 26225.2. 0.456 0.410 14 LNU228 26224.6. 0.428 0.686 7 LNU229 26112.3. 0.463 0.366 16 LNU229 26111.7. 0.455 0.448 13 LNU229 26111.5. 0.418 0.794 4 LNU241 26232.4. 0.460 0.380 15 LNU241 26233.3. 0.445 0.562 11 LNU253 26241.1. 0.424 0.720 6 LNU274 26262.2. 0.431 0.660 8 LNU274 26263.2. 0.421 0.764 5 LNU280 26162.1. 0.438 0.582 9 LNU280 26164.4. 0.424 0.725 6 LNU55 26013.3. 0.448 0.529 12 LNU81 26031.10. 0.432 0.675 8 LNU81 26034.3. 0.426 0.732 6 Table 81. “CONT.” - Control; “Ave.” - Average; “% Incr” = % increment. “RGR” = relative growth rate.

The genes listed in Tables 82 and 83 improved plant NUE when grown at standard nitrogen concentration levels. These genes produced larger plants with a larger photosynthetic area and increased biomass (fresh weight, dry weight, rosette diameter, rosette area and plot coverage) when grown under standard nitrogen conditions. The genes were cloned under the regulation of a constitutive (At6669) and root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant.

TABLE 82 Genes showing improved plant biomass production at standard nitrogen growth conditions Dry Weight [g] Fresh Weight [g] Gene P- % Gene P- % Name Event # Ave. Value incr. Name Event # Ave. Value incr. CONT. — 0.241 — 0 CONT. — 2.503 — 0 LNU100 14473.3 0.264 0.319 9 LNU104 25033.1 2.750 0.418 10 LNU104 25033.1 0.279 0.272 16 LNU104 25032.2 2.563 0.745 2 LNU104 25032.2 0.273 0.000 13 LNU106 14484.3 3.125 0.148 25 LNU104 25033.3 0.259 0.039 7 LNU114 25044.4 2.800 0.512 12 LNU104 25034.1 0.253 0.337 5 LNU114 25044.3 2.788 0.003 11 LNU106 14484.3 0.314 0.221 30 LNU114 25041.1 2.681 0.625 7 LNU106 14482.3 0.279 0.125 16 LNU155 14524.8 3.067 0.330 23 LNU106 14483.5 0.251 0.655 4 LNU155 14525.6 2.706 0.290 8 LNU114 25041.1 0.260 0.304 8 LNU218 24781.2 2.750 0.168 10 LNU114 25044.3 0.253 0.075 5 LNU218 24781.1 2.738 0.261 9 LNU114 25044.4 0.253 0.698 5 LNU218 24781.4 2.563 0.437 2 LNU114 25042.1 0.246 0.762 2 LNU28 25174.5 2.625 0.650 5 LNU155 14524.8 0.288 0.471 19 LNU4 25134.1 2.800 0.582 12 LNU155 14525.6 0.258 0.146 7 LNU40 24794.4 2.756 0.006 10 LNU213 24653.2 0.277 0.088 15 LNU48 24801.4 2.656 0.741 6 LNU218 24781.7 0.319 0.224 32 LNU63 24811.2 2.704 0.336 8 LNU218 24781.2 0.271 0.380 12 LNU7 25083.3 3.006 0.323 20 LNU218 24781.1 0.256 0.113 6 LNU8 25062.2 2.656 0.200 6 LNU218 24781.4 0.252 0.389 4 LNU8 25063.1 2.631 0.691 5 LNU23 25163.5 0.283 0.597 17 LNU8 25061.2 2.594 0.722 4 LNU23 25163.4 0.263 0.493 9 LNU94 24833.3 2.675 0.541 7 LNU28 25171.2 0.275 0.429 14 CONT. — 2.638 — 0 LNU28 25174.3 0.267 0.526 11 LNU132 14102.6 2.794 0.720 6 LNU28 25174.5 0.251 0.251 4 LNU65 24703.1 3.006 0.684 14 LNU28 25171.4 0.249 0.762 3 CONT. — 2.303 — 0 LNU4 25134.1 0.281 0.255 17 LNU113 25631.1 2.631 0.213 14 LNU4 25134.2 0.253 0.690 5 LNU113 25631.3 2.500 0.261 9 LNU4 25133.3 0.248 0.681 3 LNU120 25463.7 2.500 0.059 9 LNU40 24794.3 0.260 0.212 8 LNU120 25464.1 2.344 0.420 2 LNU40 24794.4 0.259 0.435 7 LNU148 25685.2 2.719 0.315 18 LNU46 14462.1 0.273 0.121 13 LNU148 25683.2 2.544 0.533 10 LNU48 24802.2 0.281 0.000 16 LNU148 25685.1 2.519 0.537 9 LNU48 24801.4 0.268 0.360 11 LNU287 24674.3 2.419 0.730 5 LNU48 24802.1 0.258 0.018 7 LNU287 24674.2 2.331 0.726 1 LNU63 24811.2 0.285 0.475 18 LNU37 14064.7 2.719 0.186 18 LNU63 24814.2 0.262 0.293 9 LNU37 14064.1 2.575 0.275 12 LNU7 25083.3 0.357 0.496 48 LNU37 14064.6 2.375 0.637 3 LNU7 25083.1 0.248 0.326 3 LNU5 14043.7 2.750 0.000 19 LNU8 25062.2 0.268 0.001 11 LNU65 24702.3 2.644 0.025 15 LNU8 25063.1 0.259 0.403 7 LNU65 24703.3 2.400 0.393 4 LNU8 25061.2 0.249 0.759 3 LNU65 24703.6 2.381 0.593 3 LNU94 24833.3 0.273 0.455 13 LNU68 14034.13 2.569 0.000 12 LNU94 24834.4 0.247 0.369 2 LNU68 14033.1 2.413 0.457 5 LNU94 24831.4 0.244 0.781 1 LNU68 14034.1 2.394 0.544 4 LNU96 25073.4 0.279 0.590 16 LNU71 25853.1 2.613 0.152 13 CONT. — 0.302 — 0 LNU71 25851.4 2.594 0.213 13 LNU132 14102.6 0.431 0.245 43 LNU71 25853.4 2.475 0.565 7 LNU140 14114.8 0.331 0.380 10 LNU71 25852.4 2.469 0.376 7 LNU148 25685.1 0.339 0.184 12 LNU71 25852.5 2.456 0.362 7 LNU287 24674.6 0.346 0.699 15 LNU72 24962.3 2.575 0.213 12 LNU5 14043.9 0.334 0.186 11 LNU72 24963.7 2.450 0.527 6 LNU65 24703.7 0.418 0.117 38 LNU72 24962.2 2.406 0.650 4 LNU65 24702.3 0.351 0.681 16 LNU72 24963.8 2.344 0.711 2 LNU71 25851.4 0.419 0.686 39 LNU74 25444.1 2.575 0.000 12 LNU98 25761.6 0.369 0.365 22 LNU74 25443.3 2.569 0.202 12 CONT. — 0.243 — 0 LNU74 25443.2 2.525 0.363 10 LNU113 25631.1 0.269 0.122 11 LNU82 24823.1 2.538 0.000 10 LNU113 25631.3 0.261 0.116 7 LNU84 25621.2 2.413 0.499 5 LNU148 25685.2 0.283 0.365 16 LNU84 25621.6 2.356 0.674 2 LNU148 25683.2 0.261 0.583 7 LNU84 25623.1 2.350 0.724 2 LNU148 25685.1 0.261 0.416 7 CONT. — 1.523 — 0 LNU287 24674.3 0.252 0.757 4 LNU117 25931.2 1.844 0.247 21 LNU37 14064.1 0.275 0.009 13 LNU117 25931.1 1.806 0.190 19 LNU37 14064.7 0.271 0.296 11 LNU117 25931.4 1.750 0.384 15 LNU5 14043.7 0.269 0.003 11 LNU117 25932.4 1.731 0.227 14 LNU65 24702.3 0.266 0.007 9 LNU122 25332.1 1.725 0.581 13 LNU65 24703.6 0.250 0.621 3 LNU122 25332.5 1.706 0.380 12 LNU65 24703.3 0.249 0.443 2 LNU122 25333.1 1.700 0.012 12 LNU68 14034.13 0.276 0.000 14 LNU122 25332.2 1.694 0.015 11 LNU68 14033.1 0.258 0.350 6 LNU122 25333.2 1.681 0.600 10 LNU71 25853.1 0.278 0.131 14 LNU125 25944.3 1.588 0.593 4 LNU71 25851.4 0.271 0.002 12 LNU125 25943.3 1.569 0.430 3 LNU71 25852.5 0.264 0.501 9 LNU138 14074.5 1.738 0.103 14 LNU71 25853.4 0.259 0.473 7 LNU138 14074.6 1.644 0.551 8 LNU71 25852.4 0.249 0.521 2 LNU138 14072.8 1.619 0.366 6 LNU72 24962.3 0.252 0.757 4 LNU180 24722.2 1.625 0.095 7 LNU72 24963.7 0.251 0.739 3 LNU230 25413.1 1.775 0.510 17 LNU72 24963.8 0.250 0.621 3 LNU230 25412.2 1.638 0.267 8 LNU72 24962.2 0.249 0.666 3 LNU254 25781.3 1.638 0.054 8 LNU74 25444.1 0.259 0.174 7 LNU254 25783.1 1.594 0.173 5 LNU74 25443.2 0.256 0.627 5 LNU263 25791.3 1.544 0.673 1 LNU74 25443.3 0.252 0.624 4 LNU271 25912.1 1.588 0.534 4 LNU82 24823.1 0.272 0.080 12 LNU278 25814.3 1.581 0.244 4 LNU82 24823.3 0.248 0.746 2 LNU43 14422.8 1.625 0.230 7 LNU84 25621.2 0.261 0.351 7 LNU43 14423.6 1.594 0.327 5 LNU84 25623.1 0.249 0.666 3 LNU43 14423.7 1.569 0.370 3 LNU87 24713.2 0.247 0.743 2 LNU45 25053.4 1.613 0.105 6 CONT. — 0.162 — 0 LNU67 25824.5 1.688 0.319 11 LNU117 25931.4 0.200 0.003 24 CONT. — 2.439 — 0 LNU117 25931.2 0.193 0.055 20 LNU100 14472.1 2.956 0.299 21 LNU117 25931.1 0.192 0.094 19 LNU100 14473.1 2.763 0.147 13 LNU117 25932.4 0.181 0.091 12 LNU100 14473.3 2.613 0.002 7 LNU117 25933.3 0.175 0.554 8 LNU104 25032.2 2.944 0.331 21 LNU122 25332.2 0.190 0.009 18 LNU104 25033.1 2.581 0.465 6 LNU122 25332.1 0.189 0.434 17 LNU104 25033.3 2.544 0.030 4 LNU122 25332.5 0.186 0.008 15 LNU104 25033.8 2.544 0.567 4 LNU122 25333.1 0.184 0.013 14 LNU104 25032.1 2.519 0.358 3 LNU122 25333.2 0.181 0.367 12 LNU106 14483.2 3.163 0.391 30 LNU125 25944.3 0.183 0.192 13 LNU106 14484.3 2.856 0.330 17 LNU125 25943.3 0.175 0.148 8 LNU114 25044.11 2.731 0.403 12 LNU125 25941.4 0.169 0.592 5 LNU114 25041.2 2.713 0.374 11 LNU138 14074.5 0.196 0.013 22 LNU114 25041.1 2.688 0.036 10 LNU138 14074.6 0.186 0.348 15 LNU114 25042.1 2.688 0.499 10 LNU180 24723.1 0.173 0.655 7 LNU114 25044.4 2.519 0.700 3 LNU180 24722.2 0.171 0.132 6 LNU117 25931.4 2.669 0.000 9 LNU180 24721.2 0.164 0.691 1 LNU117 25932.4 2.631 0.249 8 LNU220 25405.1 0.163 0.798 1 LNU117 25931.1 2.538 0.536 4 LNU230 25413.1 0.196 0.390 22 LNU117 25931.2 2.525 0.541 4 LNU230 25412.2 0.176 0.287 9 LNU155 14523.5 2.644 0.232 8 LNU230 25413.2 0.164 0.795 2 LNU155 14525.1 2.550 0.344 5 LNU25 14083.1 0.176 0.287 9 LNU180 24722.4 2.700 0.153 11 LNU254 25781.3 0.179 0.048 11 LNU180 24724.1 2.582 0.687 6 LNU254 25783.1 0.170 0.585 5 LNU180 24723.1 2.531 0.214 4 LNU263 25791.3 0.178 0.331 10 LNU218 24781.4 2.731 0.244 12 LNU263 25794.8 0.178 0.038 10 LNU218 24781.1 2.631 0.249 8 LNU263 25794.6 0.173 0.405 7 LNU218 24781.6 2.606 0.004 7 LNU267 25804.3 0.166 0.772 3 LNU254 25782.4 3.331 0.467 37 LNU271 25912.1 0.178 0.061 10 LNU254 25782.5 2.950 0.570 21 LNU271 25913.3 0.166 0.469 3 LNU254 25781.5 2.630 0.090 8 LNU278 25814.3 0.173 0.086 7 LNU254 25783.1 2.600 0.368 7 LNU278 25813.2 0.166 0.606 3 LNU4 25134.2 2.688 0.009 10 LNU36 25562.3 0.171 0.448 6 LNU4 25134.3 2.650 0.000 9 LNU36 25561.2 0.167 0.414 3 LNU4 25133.3 2.519 0.110 3 LNU43 14423.6 0.180 0.176 11 LNU40 24792.2 2.881 0.134 18 LNU43 14422.8 0.178 0.031 10 LNU40 24794.3 2.763 0.281 13 LNU43 14423.7 0.173 0.534 7 LNU40 24793.1 2.744 0.513 12 LNU43 14421.1 0.169 0.552 5 LNU40 24792.1 2.681 0.058 10 LNU45 25053.4 0.172 0.147 6 LNU46 14462.5 2.588 0.247 6 LNU45 25052.9 0.169 0.734 4 LNU46 14463.2 2.563 0.086 5 LNU67 25821.5 0.182 0.016 13 LNU46 14462.1 2.525 0.064 4 LNU67 25824.5 0.181 0.019 12 LNU46 14464.4 2.500 0.245 3 CONT. — 0.256 — 0 LNU48 24801.4 3.004 0.165 23 LNU100 14472.1 0.345 0.295 35 LNU48 24803.2 2.931 0.241 20 LNU100 14473.1 0.279 0.113 9 LNU48 24804.4 2.625 0.001 8 LNU100 14473.3 0.272 0.724 6 LNU48 24802.2 2.575 0.669 6 LNU104 25032.2 0.361 0.403 41 LNU48 24802.1 2.538 0.235 4 LNU106 14483.2 0.414 0.483 62 LNU63 24814.7 2.806 0.166 15 LNU106 14484.3 0.363 0.263 42 LNU63 24812.2 2.663 0.267 9 LNU114 25044.11 0.358 0.468 40 LNU63 24812.3 2.575 0.332 6 LNU114 25042.1 0.316 0.479 24 LNU63 24814.2 2.531 0.051 4 LNU114 25041.2 0.280 0.462 9 LNU7 25083.3 2.725 0.360 12 LNU114 25041.1 0.266 0.507 4 LNU7 25081.1 2.713 0.006 11 LNU117 25931.2 0.292 0.022 14 LNU7 25083.1 2.700 0.409 11 LNU117 25931.4 0.279 0.113 9 LNU8 25062.1 2.633 0.253 8 LNU117 25931.1 0.268 0.394 5 LNU8 25061.2 2.550 0.112 5 LNU117 25932.4 0.264 0.686 3 LNU94 24831.4 2.704 0.083 11 LNU155 14523.5 0.264 0.686 3 LNU94 24833.3 2.613 0.002 7 LNU180 24722.4 0.315 0.247 23 LNU94 24834.1 2.538 0.738 4 LNU180 24724.1 0.283 0.759 11 LNU96 25071.2 2.725 0.315 12 LNU180 24723.1 0.282 0.353 10 LNU96 25073.4 2.681 0.351 10 LNU218 24781.4 0.308 0.558 20 LNU96 25071.3 2.525 0.690 4 LNU218 24781.1 0.271 0.342 6 LNU96 25074.1 2.506 0.497 3 LNU254 25782.4 0.448 0.464 75 CONT. — 2.048 — 0 LNU254 25782.5 0.377 0.491 47 LNU10 25123.6 2.244 0.002 10 LNU254 25781.5 0.282 0.573 10 LNU10 25123.5 2.200 0.009 7 LNU254 25781.3 0.262 0.655 2 LNU122 25332.1 2.438 0.000 19 LNU4 25133.3 0.279 0.100 9 LNU122 25332.5 2.275 0.041 11 LNU4 25134.1 0.270 0.319 6 LNU122 25332.2 2.106 0.486 3 LNU4 25134.2 0.267 0.429 4 LNU125 25941.4 2.325 0.207 14 LNU40 24793.1 0.323 0.561 26 LNU125 25944.1 2.213 0.012 8 LNU40 24792.2 0.314 0.299 23 LNU125 25941.2 2.175 0.597 6 LNU40 24794.3 0.311 0.535 22 LNU125 25943.2 2.106 0.409 3 LNU40 24792.1 0.268 0.372 5 LNU125 25944.3 2.088 0.421 2 LNU40 24794.4 0.268 0.372 5 LNU178 14611.5 2.138 0.353 4 LNU46 14462.1 0.289 0.424 13 LNU178 14611.1 2.081 0.679 2 LNU46 14462.5 0.279 0.693 9 LNU234 25014.1 2.288 0.000 12 LNU48 24803.2 0.318 0.465 24 LNU234 25014.6 2.188 0.319 7 LNU48 24801.4 0.301 0.009 18 LNU234 25014.5 2.125 0.248 4 LNU48 24804.4 0.288 0.069 13 LNU236 25424.2 2.200 0.049 7 LNU48 24802.2 0.269 0.362 5 LNU236 25423.3 2.131 0.101 4 LNU48 24802.1 0.261 0.730 2 LNU24 24974.2 2.319 0.159 13 LNU63 24814.7 0.288 0.183 12 LNU24 24972.1 2.175 0.293 6 LNU7 25083.3 0.316 0.394 23 LNU25 14082.8 2.275 0.132 11 LNU7 25082.7 0.281 0.763 10 LNU271 25912.1 2.188 0.026 7 LNU7 25081.1 0.269 0.406 5 LNU271 25913.3 2.181 0.245 7 LNU8 25061.2 0.264 0.584 3 LNU271 25911.4 2.144 0.363 5 LNU94 24833.3 0.271 0.626 6 LNU278 25814.3 2.369 0.058 16 LNU94 24831.4 0.265 0.497 4 LNU278 25814.1 2.250 0.470 10 LNU96 25073.4 0.307 0.516 20 LNU278 25812.3 2.188 0.262 7 LNU96 25073.3 0.303 0.664 18 LNU278 25813.2 2.138 0.630 4 LNU96 25071.2 0.301 0.535 17 LNU43 14423.7 2.450 0.132 20 LNU96 25074.1 0.267 0.440 4 LNU43 14423.6 2.275 0.084 11 CONT. — 0.243 — 0 LNU43 14421.1 2.106 0.646 3 LNU10 25123.6 0.283 0.160 17 LNU43 14422.8 2.100 0.750 3 LNU10 25123.5 0.265 0.218 9 LNU45 25053.4 2.356 0.000 15 LNU10 25123.1 0.246 0.773 1 LNU45 25052.12 2.244 0.010 10 LNU122 25332.1 0.277 0.167 14 LNU45 25052.11 2.106 0.409 3 LNU122 25332.5 0.266 0.002 9 LNU67 25823.5 2.331 0.000 14 LNU125 25941.4 0.285 0.000 17 LNU67 25824.5 2.313 0.000 13 LNU125 25944.1 0.275 0.000 13 LNU67 25821.5 2.288 0.009 12 LNU125 25943.2 0.264 0.003 9 LNU67 25824.3 2.194 0.587 7 LNU125 25941.2 0.261 0.562 7 LNU67 25821.4 2.169 0.025 6 LNU157 24982.8 0.259 0.114 7 LNU9 25003.1 2.219 0.171 8 LNU178 14611.5 0.265 0.295 9 LNU9 25001.7 2.156 0.243 5 LNU234 25014.4 0.267 0.253 10 LNU9 25001.3 2.138 0.189 4 LNU234 25014.5 0.262 0.005 8 LNU9 25001.2 2.113 0.668 3 LNU234 25014.1 0.258 0.552 6 CONT. — 2.362 — 0 LNU234 25014.8 0.257 0.466 6 LNU10 25121.8 2.531 0.266 7 LNU234 25014.6 0.246 0.774 1 LNU10 25121.6 2.494 0.083 6 LNU236 25424.2 0.266 0.006 9 LNU10 25123.6 2.469 0.186 5 LNU236 25425.3 0.258 0.016 6 LNU157 24982.1 2.525 0.348 7 LNU236 25422.4 0.253 0.256 4 LNU157 24983.3 2.506 0.325 6 LNU24 24972.1 0.280 0.454 15 LNU157 24982.7 2.431 0.736 3 LNU24 24974.2 0.273 0.015 12 LNU168 24754.2 2.650 0.001 12 LNU24 24971.2 0.256 0.425 6 LNU168 24753.8 2.563 0.018 9 LNU25 14082.8 0.265 0.002 9 LNU168 24753.5 2.456 0.695 4 LNU267 25804.4 0.253 0.338 4 LNU168 24753.2 2.450 0.234 4 LNU271 25911.4 0.264 0.353 9 LNU173 25451.1 3.063 0.024 30 LNU271 25912.1 0.256 0.045 6 LNU173 25451.12 2.839 0.335 20 LNU271 25913.3 0.249 0.780 2 LNU173 25451.2 2.825 0.126 20 LNU278 25814.3 0.277 0.404 14 LNU173 25451.5 2.688 0.001 14 LNU278 25814.1 0.268 0.028 10 LNU173 25451.11 2.481 0.144 5 LNU278 25812.3 0.264 0.089 9 LNU178 14611.4 2.788 0.021 18 LNU278 25813.2 0.261 0.522 7 LNU178 14612.1 2.638 0.142 12 LNU43 14423.7 0.292 0.267 20 LNU178 14611.5 2.463 0.280 4 LNU43 14422.8 0.276 0.000 14 LNU178 14614.5 2.463 0.173 4 LNU43 14423.6 0.269 0.001 11 LNU178 14611.1 2.456 0.212 4 LNU45 25052.12 0.271 0.104 11 LNU184 25393.1 2.725 0.371 15 LNU45 25053.4 0.271 0.143 11 LNU184 25394.3 2.675 0.001 13 LNU67 25823.5 0.284 0.018 17 LNU184 25393.3 2.638 0.016 12 LNU67 25824.3 0.277 0.222 14 LNU184 25395.1 2.569 0.443 9 LNU67 25824.5 0.270 0.371 11 LNU20 24933.4 2.775 0.009 18 LNU67 25821.5 0.265 0.387 9 LNU20 24933.1 2.550 0.019 8 LNU67 25821.4 0.252 0.137 4 LNU20 24933.2 2.538 0.228 7 LNU9 25003.1 0.274 0.013 13 LNU20 24932.4 2.525 0.037 7 LNU9 25001.2 0.259 0.011 7 LNU20 24934.1 2.506 0.697 6 LNU9 25001.3 0.254 0.592 5 LNU230 25413.2 2.769 0.084 17 CONT. — 0.240 — 0 LNU230 25415.1 2.744 0.227 16 LNU10 25123.6 0.256 0.224 7 LNU230 25412.2 2.656 0.001 12 LNU10 25121.8 0.253 0.717 5 LNU230 25412.1 2.625 0.003 11 LNU10 25121.6 0.248 0.530 3 LNU230 25413.1 2.563 0.014 9 LNU157 24982.4 0.265 0.764 10 LNU236 25425.4 2.725 0.000 15 LNU157 24982.1 0.262 0.085 9 LNU236 25422.4 2.650 0.409 12 LNU157 24982.8 0.261 0.293 9 LNU236 25424.2 2.638 0.142 12 LNU168 24754.2 0.259 0.131 8 LNU236 25425.3 2.625 0.322 11 LNU168 24751.2 0.253 0.333 5 LNU236 25423.3 2.519 0.188 7 LNU168 24753.2 0.250 0.647 4 LNU24 24974.2 2.775 0.000 18 LNU173 25451.1 0.295 0.044 23 LNU24 24971.2 2.581 0.447 9 LNU173 25451.2 0.274 0.032 14 LNU24 24971.4 2.550 0.066 8 LNU173 25451.12 0.259 0.643 8 LNU24 24971.3 2.506 0.588 6 LNU173 25451.5 0.251 0.396 4 LNU263 25791.3 2.738 0.376 16 LNU173 25451.11 0.250 0.411 4 LNU263 25794.8 2.675 0.466 13 LNU178 14611.4 0.275 0.011 14 LNU263 25792.2 2.606 0.636 10 LNU178 14612.1 0.256 0.279 6 LNU263 25794.6 2.556 0.531 8 LNU178 14611.5 0.253 0.427 5 LNU263 25794.3 2.456 0.200 4 LNU178 14614.5 0.251 0.584 5 LNU276 25431.1 2.513 0.418 6 LNU184 25393.1 0.276 0.409 15 LNU276 25433.1 2.413 0.714 2 LNU184 25395.1 0.275 0.074 14 LNU279 25481.4 2.644 0.009 12 LNU184 25393.2 0.259 0.724 8 LNU279 25481.3 2.563 0.014 9 LNU184 25393.3 0.258 0.155 7 LNU279 25484.3 2.425 0.386 3 LNU184 25394.3 0.249 0.468 4 LNU279 25481.5 2.406 0.534 2 LNU20 24933.2 0.278 0.604 16 LNU279 25481.2 2.381 0.783 1 LNU20 24933.4 0.275 0.053 14 LNU36 25562.9 2.706 0.051 15 LNU20 24934.1 0.261 0.418 9 LNU36 25561.2 2.675 0.544 13 LNU20 24933.1 0.257 0.184 7 LNU36 25562.4 2.656 0.109 12 LNU230 25415.1 0.277 0.258 15 LNU36 25562.3 2.513 0.514 6 LNU230 25413.2 0.264 0.084 10 LNU36 25562.7 2.456 0.335 4 LNU230 25413.1 0.258 0.159 7 LNU53 25674.1 2.669 0.203 13 LNU230 25412.1 0.253 0.282 5 LNU53 25674.6 2.563 0.137 9 LNU230 25412.2 0.248 0.538 3 LNU53 25674.5 2.506 0.217 6 LNU236 25422.4 0.281 0.397 17 LNU53 25674.2 2.488 0.576 5 LNU236 25425.4 0.273 0.047 13 LNU56 24694.1 2.694 0.120 14 LNU236 25424.2 0.261 0.362 9 LNU56 24693.2 2.656 0.020 12 LNU236 25425.3 0.257 0.172 7 LNU56 24694.2 2.625 0.192 11 LNU24 24971.2 0.269 0.225 12 LNU56 24693.1 2.531 0.355 7 LNU24 24974.2 0.260 0.139 8 LNU73 25751.8 2.463 0.231 4 LNU24 24971.4 0.259 0.148 8 LNU73 25751.1 2.450 0.446 4 LNU24 24971.3 0.251 0.381 4 LNU9 25001.3 2.725 0.000 15 LNU263 25794.8 0.306 0.504 27 LNU9 25001.7 2.719 0.136 15 LNU263 25791.3 0.271 0.586 13 LNU9 25001.2 2.600 0.431 10 LNU263 25792.2 0.270 0.759 12 LNU9 25003.1 2.475 0.585 5 LNU263 25794.6 0.267 0.369 11 CONT. — 2.036 — 0 LNU263 25794.3 0.254 0.535 6 LNU173 25451.5 2.394 0.002 18 LNU276 25431.1 0.290 0.201 21 LNU173 25451.2 2.369 0.294 16 LNU276 25433.2 0.248 0.544 3 LNU173 25451.11 2.189 0.154 8 LNU276 25433.1 0.246 0.665 2 LNU181 25771.2 2.338 0.095 15 LNU279 25481.4 0.268 0.417 11 LNU181 25771.5 2.275 0.509 12 LNU279 25481.3 0.265 0.201 10 LNU181 25771.6 2.219 0.332 9 LNU279 25481.5 0.250 0.431 4 LNU181 25771.8 2.150 0.206 6 LNU279 25481.2 0.246 0.759 3 LNU184 25394.1 2.338 0.521 15 LNU36 25562.4 0.269 0.404 12 LNU184 25393.2 2.238 0.279 10 LNU36 25561.2 0.269 0.305 12 LNU184 25393.3 2.220 0.530 9 LNU36 25562.9 0.252 0.406 5 LNU184 25394.3 2.106 0.663 3 LNU36 25562.3 0.249 0.479 4 LNU224 25872.3 2.344 0.144 15 LNU53 25674.1 0.260 0.355 8 LNU224 25874.1 2.269 0.018 11 LNU53 25674.2 0.246 0.679 2 LNU224 25874.4 2.250 0.016 11 LNU53 25674.6 0.245 0.697 2 LNU224 25872.2 2.188 0.166 7 LNU56 24694.1 0.261 0.109 9 LNU246 25744.2 2.331 0.080 15 LNU56 24694.2 0.254 0.445 6 LNU246 25743.1 2.287 0.001 12 LNU56 24693.1 0.246 0.711 2 LNU246 25743.2 2.188 0.027 7 LNU73 25751.1 0.259 0.621 8 LNU246 25744.3 2.106 0.663 3 LNU9 25001.7 0.264 0.193 10 LNU250 25592.1 2.319 0.535 14 LNU9 25001.2 0.264 0.063 10 LNU250 25592.2 2.319 0.023 14 LNU9 25003.1 0.256 0.343 7 LNU250 25591.1 2.113 0.244 4 LNU9 25001.3 0.252 0.359 5 LNU260 26403.1 2.194 0.513 8 CONT. — 0.178 — 0 LNU260 26404.7 2.163 0.079 6 LNU131 14005.5 0.208 0.034 17 LNU260 26404.1 2.144 0.325 5 LNU131 14005.2 0.204 0.069 14 LNU260 26403.2 2.081 0.774 2 LNU135 26204.2 0.206 0.109 16 LNU276 25433.3 2.356 0.000 16 LNU135 26203.6 0.204 0.230 14 CONT. — 1.044 — 0 LNU135 26203.4 0.196 0.793 10 LNU136 14515.1 1.313 0.374 26 LNU135 26203.1 0.188 0.712 5 LNU136 14515.5 1.263 0.005 21 LNU173 25451.2 0.239 0.030 34 LNU136 14511.10 1.150 0.466 10 LNU173 25451.5 0.226 0.009 27 LNU142 27541.1 1.344 0.125 29 LNU173 25451.11 0.205 0.421 15 LNU142 27541.2 1.219 0.389 17 LNU173 25451.1 0.193 0.703 8 LNU149 26175.1 1.225 0.480 17 LNU181 25771.6 0.224 0.281 25 LNU149 26175.3 1.131 0.404 8 LNU181 25771.2 0.217 0.010 22 LNU149 26175.7 1.131 0.337 8 LNU181 25771.8 0.209 0.086 17 LNU15 14123.13 1.244 0.123 19 LNU181 25771.5 0.204 0.423 14 LNU15 14122.8 1.163 0.061 11 LNU181 25771.11 0.200 0.105 12 LNU15 14122.9 1.156 0.304 11 LNU184 25394.1 0.236 0.114 32 LNU15 14123.11 1.156 0.112 11 LNU184 25393.2 0.229 0.001 28 LNU185 26474.2 1.206 0.066 16 LNU184 25395.1 0.215 0.088 20 LNU185 26475.1 1.144 0.102 10 LNU184 25393.3 0.207 0.186 16 LNU185 26474.1 1.131 0.714 8 LNU184 25394.3 0.203 0.287 14 LNU212 25834.1 1.356 0.269 30 LNU184 25393.1 0.196 0.175 10 LNU212 25832.1 1.233 0.246 18 LNU224 25874.1 0.223 0.003 25 LNU212 25834.4 1.195 0.255 14 LNU224 25872.3 0.214 0.418 20 LNU212 25833.2 1.150 0.605 10 LNU224 25874.4 0.214 0.011 20 LNU212 25834.5 1.138 0.552 9 LNU224 25871.3 0.206 0.219 15 LNU216 25985.4 1.369 0.232 31 LNU224 25872.2 0.194 0.465 9 LNU216 25982.1 1.363 0.223 31 LNU246 25744.3 0.237 0.000 33 LNU228 26222.1 1.269 0.306 22 LNU246 25744.2 0.231 0.030 30 LNU228 26222.4 1.169 0.049 12 LNU246 25743.1 0.223 0.003 25 LNU228 26224.6 1.119 0.466 7 LNU246 25743.2 0.218 0.028 22 LNU229 26112.3 1.094 0.659 5 LNU246 25744.4 0.212 0.097 19 LNU277 25842.3 1.150 0.545 10 LNU250 25591.1 0.221 0.016 24 LNU280 26162.1 1.394 0.038 34 LNU250 25592.2 0.216 0.013 21 LNU280 26162.7 1.166 0.378 12 LNU250 25592.1 0.213 0.159 19 LNU280 26164.4 1.144 0.211 10 LNU250 25591.3 0.186 0.684 4 LNU55 26015.1 1.356 0.006 30 LNU260 26404.1 0.215 0.032 20 LNU55 26015.3 1.219 0.011 17 LNU260 26404.7 0.211 0.027 18 LNU81 26034.3 1.194 0.140 14 LNU260 26403.1 0.204 0.119 15 LNU81 26031.2 1.125 0.172 8 LNU260 26403.2 0.195 0.312 9 CONT. — 1.494 — 0 LNU260 26404.8 0.185 0.681 4 LNU119 26141.1 1.806 0.082 21 LNU276 25433.3 0.218 0.006 22 LNU119 26142.8 1.744 0.472 17 LNU276 25433.6 0.213 0.066 19 LNU119 26144.1 1.613 0.619 8 LNU276 25433.5 0.188 0.475 5 LNU119 26144.2 1.606 0.157 8 LNU276 25431.1 0.185 0.614 4 LNU119 26142.5 1.575 0.705 5 LNU279 25484.3 0.216 0.017 21 LNU130 24913.5 1.856 0.340 24 LNU279 25481.5 0.215 0.046 20 LNU130 24911.7 1.813 0.030 21 LNU279 25481.3 0.199 0.223 11 LNU130 24913.6 1.700 0.219 14 LNU279 25481.4 0.184 0.646 3 LNU130 24912.7 1.675 0.371 12 LNU3 26124.3 0.218 0.073 22 LNU136 14514.8 1.906 0.106 28 LNU3 26122.2 0.205 0.050 15 LNU136 14511.10 1.731 0.165 16 LNU3 26123.5 0.203 0.162 14 LNU136 14515.1 1.725 0.192 15 LNU3 26124.1 0.193 0.528 8 LNU142 27546.2 2.000 0.300 34 LNU33 25552.2 0.223 0.023 25 LNU142 27541.2 1.919 0.001 28 LNU33 25551.1 0.186 0.589 4 LNU142 27545.1 1.844 0.100 23 CONT. — 0.079 — 0 LNU142 27546.1 1.769 0.266 18 LNU119 26142.5 0.085 0.725 8 LNU142 27541.1 1.625 0.157 9 LNU130 24914.5 0.085 0.186 8 LNU149 26174.7 1.756 0.306 18 LNU130 24913.6 0.084 0.792 7 LNU149 26174.6 1.659 0.375 11 LNU130 24912.7 0.083 0.422 5 LNU149 26175.3 1.638 0.321 10 LNU136 14515.5 0.108 0.000 38 LNU149 26174.8 1.538 0.272 3 LNU136 14515.1 0.108 0.377 37 LNU15 14122.8 1.894 0.001 27 LNU136 14511.10 0.092 0.107 17 LNU15 14123.11 1.713 0.281 15 LNU142 27541.1 0.111 0.000 41 LNU15 14124.12 1.625 0.510 9 LNU142 27541.2 0.093 0.086 18 LNU185 26474.1 1.806 0.283 21 LNU142 27545.1 0.088 0.528 12 LNU185 26473.1 1.750 0.206 17 LNU142 27546.2 0.085 0.411 8 LNU185 26475.1 1.694 0.102 13 LNU149 26175.1 0.104 0.357 33 LNU185 26474.2 1.644 0.376 10 LNU149 26175.3 0.095 0.463 21 LNU212 25834.4 2.106 0.000 41 LNU149 26175.7 0.084 0.421 7 LNU212 25834.5 2.094 0.000 40 LNU15 14123.11 0.104 0.000 33 LNU212 25834.1 2.019 0.079 35 LNU15 14123.13 0.102 0.304 30 LNU212 25833.2 1.944 0.118 30 LNU15 14122.9 0.100 0.016 27 LNU212 25833.1 1.600 0.705 7 LNU15 14122.8 0.099 0.033 26 LNU216 25984.1 2.238 0.043 50 LNU185 26474.2 0.099 0.001 26 LNU216 25982.2 2.169 0.073 45 LNU185 26473.1 0.088 0.651 12 LNU216 25985.4 2.113 0.239 41 LNU185 26474.1 0.088 0.084 11 LNU216 25984.6 2.094 0.000 40 LNU212 25832.1 0.115 0.117 46 LNU216 25982.1 1.850 0.000 24 LNU212 25834.4 0.107 0.172 36 LNU228 26222.1 2.688 0.000 80 LNU212 25834.1 0.101 0.043 29 LNU228 26224.7 2.381 0.040 59 LNU212 25833.2 0.094 0.565 19 LNU228 26222.4 2.301 0.066 54 LNU212 25834.5 0.094 0.425 19 LNU228 26225.2 2.256 0.000 51 LNU216 25982.1 0.114 0.219 45 LNU228 26224.6 2.081 0.244 39 LNU216 25985.4 0.108 0.055 37 LNU229 26111.5 2.194 0.002 47 LNU228 26222.1 0.103 0.001 30 LNU229 26112.4 2.175 0.000 46 LNU228 26222.4 0.098 0.002 24 LNU229 26111.7 2.163 0.000 45 LNU228 26224.6 0.094 0.238 19 LNU229 26112.3 2.038 0.243 36 LNU228 26224.7 0.083 0.422 5 LNU229 26114.1 1.931 0.185 29 LNU229 26112.3 0.096 0.466 22 LNU241 26232.4 2.163 0.000 45 LNU253 26241.1 0.083 0.514 6 LNU241 26234.1 2.163 0.018 45 LNU277 25842.3 0.099 0.370 26 LNU241 26232.1 1.881 0.209 26 LNU277 25844.4 0.089 0.166 14 LNU241 26233.2 1.881 0.383 26 LNU277 25844.3 0.082 0.765 4 LNU241 26233.3 1.744 0.415 17 LNU280 26162.1 0.114 0.002 45 LNU253 26242.1 2.175 0.000 46 LNU280 26162.7 0.096 0.081 23 LNU253 26241.1 2.100 0.000 41 LNU280 26164.4 0.092 0.053 17 LNU253 26243.3 2.069 0.169 38 LNU280 26164.2 0.083 0.374 6 LNU253 26245.1 1.794 0.707 20 LNU55 26015.1 0.097 0.100 23 LNU253 26244.2 1.781 0.165 19 LNU55 26015.3 0.094 0.006 20 LNU274 26264.2 2.331 0.030 56 LNU81 26031.2 0.099 0.077 26 LNU274 26265.1 2.238 0.147 50 LNU81 26034.3 0.092 0.311 17 LNU274 26262.2 2.225 0.087 49 LNU81 26031.10 0.088 0.570 11 LNU274 26263.2 2.225 0.113 49 CONT. — 0.150 — 0 LNU274 26261.3 2.113 0.008 41 LNU119 26142.8 0.160 0.721 7 LNU277 25844.3 2.094 0.000 40 LNU119 26141.1 0.157 0.673 5 LNU277 25842.3 2.013 0.028 35 LNU130 24913.5 0.168 0.234 12 LNU277 25844.4 1.988 0.136 33 LNU130 24913.6 0.159 0.303 6 LNU277 25841.3 1.881 0.230 26 LNU130 24911.7 0.156 0.412 4 LNU277 25845.1 1.625 0.589 9 LNU136 14514.8 0.193 0.421 28 LNU280 26162.1 2.469 0.006 65 LNU136 14511.10 0.164 0.110 10 LNU280 26164.4 2.263 0.001 51 LNU136 14515.1 0.163 0.361 8 LNU280 26162.7 2.094 0.368 40 LNU142 27546.2 0.176 0.494 17 LNU280 26164.3 1.888 0.255 26 LNU142 27541.2 0.171 0.037 14 LNU280 26164.2 1.700 0.487 14 LNU142 27545.1 0.171 0.032 14 LNU55 26013.9 2.219 0.067 49 LNU142 27546.1 0.153 0.768 2 LNU55 26013.3 2.181 0.000 46 LNU15 14123.11 0.171 0.491 14 LNU55 26015.1 1.881 0.001 26 LNU15 14122.8 0.166 0.087 11 LNU81 26034.2 1.956 0.572 31 LNU15 14124.12 0.160 0.721 7 LNU81 26031.10 1.781 0.671 19 LNU185 26473.1 0.174 0.019 16 LNU81 26034.3 1.581 0.514 6 LNU185 26474.1 0.170 0.236 13 LNU185 26475.1 0.157 0.757 5 LNU212 25834.5 0.186 0.004 24 LNU212 25833.2 0.178 0.250 18 LNU212 25834.1 0.175 0.016 17 LNU212 25834.4 0.175 0.015 17 LNU216 25982.1 0.194 0.348 30 LNU216 25982.2 0.192 0.002 28 LNU216 25985.4 0.179 0.237 19 LNU216 25984.1 0.178 0.146 18 LNU216 25984.6 0.171 0.204 14 LNU228 26222.1 0.251 0.000 67 LNU228 26222.4 0.206 0.108 37 LNU228 26224.7 0.199 0.024 33 LNU228 26225.2 0.196 0.081 31 LNU228 26224.6 0.171 0.365 14 LNU229 26111.7 0.190 0.006 27 LNU229 26111.5 0.184 0.056 23 LNU229 26112.4 0.184 0.007 23 LNU229 26114.1 0.167 0.397 11 LNU229 26112.3 0.163 0.123 9 LNU241 26232.4 0.190 0.002 27 LNU241 26234.1 0.183 0.008 22 LNU241 26232.1 0.171 0.129 14 LNU241 26233.2 0.169 0.467 13 LNU241 26233.3 0.153 0.719 2 LNU253 26242.1 0.188 0.003 25 LNU253 26241.1 0.185 0.005 23 LNU253 26243.3 0.171 0.057 14 LNU253 26244.2 0.156 0.523 4 LNU274 26264.2 0.211 0.000 40 LNU274 26263.2 0.193 0.025 28 LNU274 26262.2 0.190 0.269 27 LNU274 26261.3 0.188 0.003 25 LNU274 26265.1 0.179 0.465 20 LNU277 25844.3 0.198 0.003 32 LNU277 25841.3 0.181 0.434 20 LNU277 25844.4 0.171 0.204 14 LNU277 25842.3 0.160 0.348 7 LNU280 26162.1 0.216 0.134 44 LNU280 26164.4 0.191 0.002 28 LNU280 26162.7 0.169 0.673 13 LNU280 26164.3 0.169 0.491 13 LNU55 26013.3 0.194 0.042 29 LNU55 26013.9 0.190 0.227 27 LNU55 26015.1 0.168 0.057 12 LNU81 26034.2 0.174 0.732 16 Table 82. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

TABLE 83 Genes showing improved plant biomass production at standard nitrogen growth conditions Rosette Rosette Area Plot Coverage Diameter [cm] [cm2] [%] Gene P- % Gene P- % Gene P- % Name Event # Ave. Value incr. Name Event # Ave. Value incr. Name Event # Ave. Value incr. CONT. — 3.65 — 0 CONT. — 4.53 — 0 CONT. — 35.85 — 0 LNU100 14471.4 4.39 0.208 20 LNU100 14471.4 6.19 0.343 37 LNU100 14471.4 49.56 0.334 38 LNU100 14474.3 4.22 0.051 16 LNU100 14474.3 5.82 0.061 28 LNU100 14474.3 46.53 0.052 30 LNU100 14472.2 4.16 0.159 14 LNU100 14473.3 5.78 0.148 27 LNU100 14473.3 46.21 0.136 29 LNU100 14473.3 4.07 0.105 12 LNU100 14472.2 5.61 0.199 24 LNU100 14472.2 44.86 0.184 25 LNU104 25032.2 4.52 0.083 24 LNU104 25032.2 7.12 0.090 57 LNU104 25032.2 56.93 0.085 59 LNU104 25033.1 4.46 0.131 22 LNU104 25033.1 6.47 0.063 43 LNU104 25033.1 51.77 0.056 44 LNU104 25032.1 4.32 0.074 18 LNU104 25032.1 6.29 0.129 39 LNU104 25032.1 50.31 0.121 40 LNU104 25033.3 4.26 0.023 17 LNU104 25033.3 6.07 0.000 34 LNU104 25033.3 48.53 0.000 35 LNU104 25034.1 3.84 0.276 5 LNU104 25034.1 5.06 0.235 12 LNU104 25034.1 40.49 0.204 13 LNU106 14482.3 4.27 0.401 17 LNU106 14482.3 5.94 0.358 31 LNU106 14482.3 47.55 0.347 33 LNU106 14483.5 4.19 0.000 15 LNU106 14483.5 5.72 0.063 26 LNU106 14483.5 45.73 0.054 28 LNU106 14483.2 4.11 0.218 13 LNU106 14483.2 5.69 0.340 26 LNU106 14483.2 45.51 0.326 27 LNU106 14481.1 3.77 0.065 3 LNU114 25041.1 6.77 0.000 49 LNU114 25041.1 54.13 0.000 51 LNU114 25041.1 4.54 0.000 24 LNU114 25042.1 5.62 0.144 24 LNU114 25042.1 44.92 0.130 25 LNU114 25042.1 4.13 0.084 13 LNU114 25041.2 5.18 0.018 14 LNU114 25041.2 41.40 0.013 15 LNU114 25041.2 3.96 0.112 9 LNU155 14525.6 5.63 0.118 24 LNU155 14525.6 45.03 0.105 26 LNU155 14525.6 4.16 0.115 14 LNU155 14525.1 5.43 0.517 20 LNU155 14525.1 43.44 0.499 21 LNU155 14525.1 3.97 0.517 9 LNU213 24653.2 6.87 0.000 51 LNU213 24653.2 54.92 0.000 53 LNU213 24653.2 4.55 0.000 25 LNU213 24652.4 6.04 0.458 33 LNU213 24652.4 48.29 0.448 35 LNU213 24652.4 4.25 0.477 16 LNU213 24653.1 5.21 0.001 15 LNU213 24653.1 41.64 0.001 16 LNU213 24653.1 3.88 0.004 6 LNU218 24781.1 6.41 0.167 41 LNU218 24781.1 51.27 0.159 43 LNU213 24654.4 3.79 0.713 4 LNU218 24781.7 6.10 0.215 35 LNU218 24781.7 48.78 0.206 36 LNU218 24781.1 4.43 0.199 21 LNU218 24781.2 5.24 0.306 16 LNU218 24781.2 41.96 0.282 17 LNU218 24781.7 4.30 0.190 18 LNU23 25163.5 6.90 0.010 52 LNU23 25163.5 55.20 0.008 54 LNU218 24781.2 3.98 0.000 9 LNU23 25163.6 5.17 0.442 14 LNU23 25163.6 41.39 0.416 15 LNU23 25163.5 4.47 0.000 23 LNU28 25171.2 6.00 0.122 32 LNU28 25171.2 47.99 0.112 34 LNU23 25163.6 3.87 0.342 6 LNU28 25174.3 5.31 0.173 17 LNU28 25174.3 42.47 0.154 18 LNU23 25163.4 3.72 0.764 2 LNU28 25171.1 5.15 0.003 14 LNU28 25171.1 38.56 0.403 8 LNU28 25171.2 4.17 0.193 14 LNU28 25171.4 4.82 0.522 6 LNU28 25171.4 38.54 0.464 8 LNU28 25171.1 4.04 0.215 11 LNU28 25174.5 4.72 0.769 4 LNU28 25174.5 37.74 0.713 5 LNU28 25174.3 3.93 0.086 8 LNU4 25134.1 6.45 0.020 42 LNU4 25134.1 51.60 0.015 44 LNU28 25171.4 3.82 0.422 5 LNU4 25133.3 5.78 0.001 28 LNU4 25133.3 46.23 0.001 29 LNU28 25174.5 3.74 0.715 3 LNU4 25134.3 5.42 0.390 20 LNU4 25134.3 43.35 0.372 21 LNU4 25134.1 4.33 0.052 19 LNU4 25134.2 5.00 0.352 10 LNU4 25134.2 40.03 0.315 12 LNU4 25133.3 4.26 0.004 17 LNU4 25131.1 4.82 0.730 6 LNU4 25131.1 38.56 0.689 8 LNU4 25134.3 3.95 0.423 8 LNU40 24794.3 6.09 0.075 34 LNU40 24794.3 48.69 0.066 36 LNU4 25134.2 3.82 0.388 5 LNU40 24794.4 5.79 0.278 28 LNU40 24794.4 46.29 0.265 29 LNU4 25131.1 3.78 0.702 4 LNU40 24792.1 4.96 0.024 9 LNU40 24792.1 39.69 0.019 11 LNU40 24794.3 4.22 0.021 16 LNU40 24792.2 4.93 0.568 9 LNU40 24792.2 39.44 0.528 10 LNU40 24794.4 4.12 0.136 13 LNU46 14464.4 6.71 0.233 48 LNU46 14464.4 53.69 0.227 50 LNU40 24792.1 3.78 0.048 4 LNU46 14463.1 6.56 0.339 45 LNU46 14463.1 52.50 0.331 46 LNU46 14463.1 4.49 0.310 23 LNU46 14462.5 6.24 0.000 38 LNU46 14462.5 49.91 0.000 39 LNU46 14464.4 4.38 0.219 20 LNU46 14462.1 5.39 0.339 19 LNU46 14462.1 40.68 0.601 13 LNU46 14462.5 4.34 0.000 19 LNU48 24801.4 7.25 0.000 60 LNU48 24801.4 58.02 0.000 62 LNU46 14462.1 3.98 0.418 9 LNU48 24802.2 6.41 0.050 41 LNU48 24802.2 51.27 0.044 43 LNU48 24801.4 4.61 0.000 26 LNU48 24802.1 6.01 0.051 33 LNU48 24802.1 48.11 0.044 34 LNU48 24802.1 4.41 0.039 21 LNU63 24814.2 6.06 0.418 34 LNU63 24814.2 48.51 0.408 35 LNU48 24802.2 4.33 0.026 19 LNU63 24812.2 5.31 0.254 17 LNU63 24812.2 42.49 0.233 19 LNU63 24814.2 4.25 0.454 17 LNU63 24814.3 5.22 0.391 15 LNU63 24814.3 41.77 0.367 17 LNU63 24814.3 3.97 0.477 9 LNU63 24811.2 4.78 0.772 6 LNU7 25081.1 45.92 0.015 28 LNU63 24812.2 3.93 0.357 8 LNU7 25081.1 5.74 0.019 27 LNU7 25083.1 44.18 0.044 23 LNU7 25083.1 4.12 0.000 13 LNU7 25083.1 5.52 0.053 22 LNU7 25083.3 40.05 0.530 12 LNU7 25081.1 4.09 0.000 12 LNU7 25083.3 5.01 0.563 10 LNU7 25082.2 37.72 0.193 5 LNU7 25083.3 3.74 0.704 3 LNU7 25082.2 4.71 0.267 4 LNU8 25063.6 46.26 0.036 29 LNU7 25082.2 3.73 0.217 2 LNU8 25063.6 5.78 0.043 28 LNU8 25062.2 42.10 0.315 17 LNU8 25063.6 4.19 0.064 15 LNU8 25062.2 5.26 0.338 16 LNU8 25061.2 38.84 0.393 8 LNU8 25062.2 3.85 0.582 6 LNU8 25061.2 4.86 0.447 7 LNU8 25063.1 38.51 0.289 7 LNU8 25061.2 3.84 0.299 5 LNU8 25063.1 4.81 0.351 6 LNU94 24833.3 47.02 0.289 31 LNU8 25063.1 3.77 0.071 3 LNU94 24833.3 5.88 0.301 30 LNU94 24831.4 45.54 0.000 27 LNU94 24833.3 4.12 0.202 13 LNU94 24831.4 5.69 0.000 26 LNU94 24834.4 42.80 0.036 19 LNU94 24831.4 4.00 0.001 10 LNU94 24834.4 5.35 0.046 18 LNU94 24833.1 39.16 0.691 9 LNU94 24834.4 3.99 0.101 9 LNU94 24833.1 4.89 0.724 8 LNU96 25073.3 42.52 0.451 19 LNU94 24833.1 3.77 0.724 3 LNU96 25073.3 5.31 0.472 17 LNU96 25071.3 41.84 0.050 17 LNU96 25073.3 4.05 0.372 11 LNU96 25071.3 5.23 0.063 15 CONT. — 56.10 — 0 LNU96 25071.3 3.92 0.111 7 CONT. — 7.01 — 0 LNU148 25685.6 59.24 0.687 6 LNU96 25073.4 3.76 0.755 3 LNU148 25685.6 7.41 0.687 6 LNU5 14042.7 61.42 0.016 9 CONT. — 4.37 — 0 LNU5 14042.7 7.68 0.016 9 LNU72 24962.3 60.29 0.584 7 LNU5 14042.7 4.56 0.028 4 LNU72 24962.3 7.54 0.584 7 LNU98 25763.2 58.27 0.297 4 LNU72 24962.3 4.58 0.611 5 LNU98 25763.2 7.28 0.297 4 CONT. — 49.17 — 0 LNU98 25763.2 4.53 0.195 4 CONT. — 6.21 — 0 LNU113 25631.1 57.73 0.070 17 CONT. — 4.09 — 0 LNU113 25631.1 7.22 0.082 16 LNU113 25631.3 56.54 0.380 15 LNU113 25631.1 4.59 0.128 12 LNU113 25631.3 7.07 0.406 14 LNU124 14504.5 56.31 0.308 15 LNU113 25631.3 4.47 0.296 9 LNU124 14504.5 7.04 0.335 13 LNU148 25685.1 56.54 0.036 15 LNU124 14504.5 4.52 0.176 11 LNU148 25685.1 7.07 0.044 14 LNU148 25685.2 54.69 0.758 11 LNU132 14102.9 4.33 0.705 6 LNU148 25685.2 6.84 0.778 10 LNU37 14064.7 63.16 0.018 28 LNU148 25685.1 4.40 0.068 7 LNU37 14064.7 7.89 0.021 27 LNU37 14064.6 54.98 0.659 12 LNU287 24674.3 4.30 0.654 5 LNU37 14064.6 6.87 0.684 11 LNU5 14043.9 63.55 0.068 29 LNU37 14064.7 4.77 0.034 16 LNU5 14043.9 7.94 0.075 28 LNU5 14043.7 51.12 0.681 4 LNU37 14064.6 4.55 0.461 11 LNU5 14043.7 6.39 0.757 3 LNU65 24702.3 52.18 0.687 6 LNU5 14043.9 4.52 0.129 11 LNU65 24702.3 6.52 0.734 5 LNU68 14034.13 64.85 0.369 32 LNU65 24703.6 4.32 0.434 6 LNU68 14034.13 8.11 0.379 31 LNU71 25852.5 62.11 0.105 26 LNU65 24702.3 4.28 0.759 5 LNU71 25852.5 7.76 0.114 25 LNU71 25853.1 61.33 0.002 25 LNU68 14034.13 4.73 0.410 16 LNU71 25853.1 7.67 0.003 23 LNU71 25851.4 55.90 0.258 14 LNU71 25853.1 4.76 0.000 16 LNU71 25851.4 6.99 0.287 13 LNU72 24963.7 55.78 0.372 13 LNU71 25852.5 4.67 0.198 14 LNU72 24963.7 6.97 0.402 12 LNU72 24963.8 50.14 0.789 2 LNU71 25851.4 4.57 0.245 12 LNU74 25443.3 7.10 0.538 14 LNU74 25443.3 56.78 0.515 15 LNU72 24963.7 4.47 0.518 9 LNU82 24823.1 6.66 0.450 7 LNU82 24823.1 53.30 0.399 8 LNU72 24963.8 4.16 0.749 2 LNU84 25621.2 6.58 0.562 6 LNU84 25621.2 52.68 0.506 7 LNU74 25443.3 4.58 0.398 12 LNU84 25621.4 6.55 0.392 5 LNU84 25621.4 52.36 0.324 6 LNU74 25444.1 4.20 0.485 3 CONT. — 7.69 — 0 CONT. — 60.12 — 0 LNU82 24823.1 4.32 0.164 6 LNU117 25931.4 10.65 0.009 38 LNU117 25931.4 85.18 0.007 42 LNU84 25621.2 4.39 0.279 7 LNU117 25933.3 10.29 0.003 34 LNU117 25933.3 82.33 0.005 37 LNU84 25621.4 4.25 0.299 4 LNU117 25931.1 8.36 0.259 9 LNU117 25931.1 66.92 0.211 11 LNU87 24712.1 4.29 0.647 5 LNU117 25932.4 8.00 0.520 4 LNU117 25932.4 63.99 0.400 6 CONT. — 4.56 — 0 LNU117 25931.2 7.88 0.794 2 LNU117 25931.2 63.01 0.633 5 LNU117 25931.4 5.36 0.121 18 LNU122 25333.2 10.01 0.004 30 LNU122 25333.2 80.11 0.007 33 LNU117 25933.3 5.32 0.013 17 LNU122 25333.1 9.61 0.013 25 LNU122 25333.1 76.90 0.015 28 LNU117 25931.1 4.81 0.421 5 LNU122 25332.2 9.57 0.061 24 LNU122 25332.2 76.60 0.047 27 LNU117 25932.4 4.74 0.194 4 LNU122 25332.5 9.29 0.340 21 LNU122 25332.5 74.32 0.298 24 LNU117 25931.2 4.72 0.564 3 LNU122 25332.1 9.00 0.309 17 LNU122 25332.1 72.00 0.260 20 LNU122 25333.2 5.09 0.046 12 LNU125 25941.4 9.65 0.009 25 LNU125 25941.4 77.19 0.012 28 LNU122 25332.2 5.06 0.023 11 LNU125 25944.3 8.58 0.410 12 LNU125 25944.3 68.65 0.342 14 LNU122 25332.1 5.01 0.165 10 LNU125 25941.2 8.07 0.588 5 LNU125 25941.2 64.54 0.464 7 LNU122 25333.1 4.99 0.040 9 LNU138 14074.6 9.67 0.108 26 LNU138 14074.6 77.36 0.083 29 LNU122 25332.5 4.93 0.447 8 LNU138 14074.5 9.38 0.024 22 LNU138 14074.5 75.02 0.025 25 LNU125 25941.4 5.22 0.062 14 LNU180 24722.2 8.14 0.371 6 LNU180 24722.2 65.08 0.298 8 LNU125 25944.3 4.83 0.100 6 LNU220 25405.1 8.16 0.413 6 LNU180 24724.1 62.46 0.776 4 LNU138 14074.5 5.17 0.005 13 LNU220 25405.6 8.07 0.724 5 LNU220 25405.1 65.27 0.324 9 LNU138 14074.6 5.12 0.008 12 LNU230 25413.1 9.23 0.467 20 LNU220 25405.6 64.54 0.617 7 LNU180 24724.1 4.69 0.503 3 LNU230 25412.2 9.22 0.477 20 LNU220 25405.3 63.52 0.713 6 LNU180 24722.2 4.68 0.399 3 LNU230 25413.2 8.92 0.659 16 LNU220 25405.2 62.55 0.703 4 LNU180 24723.1 4.64 0.532 2 LNU25 14083.7 8.47 0.614 10 LNU230 25413.1 73.84 0.427 23 LNU220 25405.6 4.82 0.397 6 LNU25 14083.1 8.41 0.174 9 LNU230 25412.2 73.79 0.437 23 LNU230 25413.1 5.04 0.391 11 LNU25 14082.8 8.39 0.185 9 LNU230 25413.2 71.33 0.619 19 LNU230 25412.2 4.99 0.456 9 LNU25 14082.9 8.01 0.505 4 LNU25 14083.7 67.72 0.546 13 LNU230 25413.2 4.89 0.710 7 LNU254 25782.4 8.05 0.580 5 LNU25 14083.1 67.24 0.158 12 LNU230 25412.1 4.66 0.755 2 LNU254 25781.3 7.96 0.605 3 LNU25 14082.8 67.09 0.166 12 LNU25 14082.8 4.86 0.066 7 LNU263 25791.3 9.99 0.294 30 LNU25 14082.9 64.08 0.390 7 LNU25 14082.9 4.79 0.207 5 LNU263 25794.8 9.48 0.103 23 LNU254 25782.4 64.44 0.454 7 LNU25 14083.1 4.77 0.146 5 LNU267 25804.3 8.13 0.675 6 LNU254 25781.3 63.70 0.462 6 LNU25 14083.7 4.70 0.756 3 LNU271 25912.1 8.11 0.778 5 LNU263 25791.3 79.91 0.265 33 LNU254 25781.3 4.71 0.283 3 LNU278 25814.3 8.80 0.498 14 LNU263 25794.8 75.84 0.080 26 LNU254 25782.5 4.70 0.435 3 LNU278 25814.1 8.01 0.539 4 LNU263 25794.6 61.72 0.759 3 LNU254 25782.4 4.68 0.777 3 LNU278 25812.3 7.95 0.661 3 LNU267 25804.3 65.00 0.570 8 LNU263 25791.3 5.30 0.257 16 LNU36 25562.3 8.31 0.386 8 LNU271 25913.3 63.74 0.687 6 LNU263 25794.8 5.21 0.133 14 LNU43 14422.8 8.81 0.099 14 LNU278 25814.3 70.43 0.444 17 LNU263 25794.6 4.65 0.738 2 LNU43 14423.6 8.66 0.549 13 LNU278 25814.1 64.05 0.414 7 LNU267 25804.3 4.66 0.579 2 LNU43 14421.1 8.62 0.403 12 LNU278 25812.3 63.60 0.510 6 LNU271 25913.3 4.84 0.510 6 LNU45 25053.4 9.41 0.017 22 LNU36 25562.3 66.51 0.306 11 LNU271 25912.1 4.73 0.729 4 LNU67 25824.5 10.02 0.103 30 LNU43 14422.8 70.46 0.087 17 LNU278 25814.3 4.79 0.556 5 LNU67 25821.5 9.56 0.213 24 LNU43 14423.6 69.31 0.490 15 LNU278 25814.1 4.71 0.273 3 LNU67 25823.5 7.91 0.742 3 LNU43 14421.1 68.95 0.337 15 LNU278 25812.3 4.65 0.552 2 CONT. — 5.51 — 0 LNU43 14422.9 61.94 0.683 3 LNU36 25562.3 4.84 0.280 6 LNU100 14472.1 7.25 0.214 32 LNU45 25053.4 75.26 0.020 25 LNU43 14421.1 5.03 0.265 10 LNU100 14473.1 6.68 0.126 21 LNU67 25824.5 80.13 0.080 33 LNU43 14423.6 4.98 0.534 9 LNU100 14473.3 6.65 0.202 21 LNU67 25821.5 76.49 0.178 27 LNU43 14422.8 4.91 0.059 8 LNU104 25032.2 8.31 0.061 51 LNU67 25823.5 63.25 0.582 5 LNU43 14422.9 4.69 0.341 3 LNU104 25033.3 7.18 0.094 30 LNU67 25821.4 61.30 0.796 2 LNU45 25053.4 5.08 0.048 12 LNU104 25032.1 6.09 0.137 10 CONT. — 43.28 — 0 LNU67 25824.5 5.33 0.013 17 LNU106 14483.2 6.84 0.395 24 LNU100 14472.1 58.02 0.197 34 LNU67 25821.5 5.01 0.414 10 LNU106 14483.5 6.54 0.277 19 LNU100 14473.1 53.48 0.103 24 LNU67 25823.5 4.69 0.594 3 LNU106 14481.1 6.47 0.545 17 LNU100 14473.3 53.22 0.176 23 LNU67 25821.4 4.66 0.659 2 LNU106 14484.3 5.67 0.734 3 LNU104 25032.2 66.45 0.052 54 CONT. — 4.04 — 0 LNU114 25041.2 7.36 0.173 34 LNU104 25033.3 57.45 0.078 33 LNU100 14472.1 4.66 0.122 15 LNU114 25044.4 6.15 0.537 12 LNU104 25032.1 48.73 0.095 13 LNU100 14473.1 4.55 0.001 12 LNU114 25041.1 5.89 0.758 7 LNU104 25033.8 44.10 0.672 2 LNU100 14473.3 4.45 0.361 10 LNU117 25931.4 6.66 0.186 21 LNU106 14483.2 54.74 0.371 26 LNU104 25032.2 4.96 0.095 23 LNU117 25931.1 5.91 0.423 7 LNU106 14483.5 52.35 0.247 21 LNU104 25033.3 4.73 0.150 17 LNU155 14523.5 5.99 0.663 9 LNU106 14481.1 51.74 0.511 20 LNU104 25032.1 4.25 0.102 5 LNU218 24781.4 6.59 0.002 20 LNU114 25041.2 58.92 0.158 36 LNU106 14483.2 4.55 0.371 13 LNU218 24781.6 6.06 0.519 10 LNU114 25044.4 49.23 0.487 14 LNU106 14481.1 4.50 0.556 11 LNU218 24781.1 5.78 0.271 5 LNU114 25041.1 47.15 0.701 9 LNU106 14483.5 4.40 0.277 9 LNU254 25782.4 6.21 0.006 13 LNU114 25042.1 45.58 0.794 5 LNU106 14484.3 4.18 0.404 3 LNU4 25133.3 6.38 0.118 16 LNU117 25931.4 53.31 0.161 23 LNU114 25041.2 4.64 0.072 15 LNU4 25134.3 6.31 0.001 14 LNU117 25931.1 47.29 0.337 9 LNU114 25044.4 4.22 0.627 4 LNU4 25134.2 6.01 0.517 9 LNU155 14523.5 47.93 0.605 11 LNU114 25041.1 4.20 0.685 4 LNU40 24792.1 7.46 0.301 35 LNU218 24781.4 52.74 0.001 22 LNU117 25931.4 4.55 0.106 12 LNU40 24794.4 6.15 0.536 12 LNU218 24781.6 48.47 0.459 12 LNU117 25931.1 4.15 0.711 3 LNU40 24794.3 5.94 0.458 8 LNU218 24781.1 46.21 0.160 7 LNU155 14523.5 4.30 0.554 6 LNU40 24792.2 5.64 0.769 2 LNU254 25782.4 49.64 0.004 15 LNU218 24781.4 4.53 0.000 12 LNU46 14462.5 7.95 0.292 44 LNU4 25133.3 51.05 0.090 18 LNU218 24781.6 4.39 0.371 9 LNU46 14462.1 7.10 0.000 29 LNU4 25134.3 50.45 0.001 17 LNU218 24781.1 4.24 0.138 5 LNU48 24801.4 7.08 0.007 28 LNU4 25134.2 48.07 0.452 11 LNU254 25782.4 4.26 0.046 5 LNU48 24802.1 6.43 0.546 17 LNU40 24792.1 59.71 0.285 38 LNU4 25133.3 4.50 0.233 11 LNU48 24803.2 5.82 0.623 6 LNU40 24794.4 49.18 0.486 14 LNU4 25134.2 4.26 0.337 5 LNU63 24814.2 6.82 0.060 24 LNU40 24794.3 47.49 0.377 10 LNU4 25134.3 4.25 0.069 5 LNU63 24814.6 6.19 0.055 12 LNU40 24792.2 45.13 0.611 4 LNU40 24792.1 4.82 0.229 19 LNU63 24812.3 5.68 0.410 3 LNU46 14462.5 63.58 0.280 47 LNU40 24794.4 4.40 0.436 9 LNU7 25081.1 6.87 0.077 25 LNU46 14462.1 56.79 0.000 31 LNU40 24794.3 4.20 0.287 4 LNU7 25083.1 5.88 0.710 7 LNU48 24801.4 53.00 0.046 22 LNU40 24792.2 4.16 0.413 3 LNU7 25083.3 5.67 0.536 3 LNU48 24802.1 51.43 0.511 19 LNU46 14462.5 4.78 0.258 18 LNU8 25063.1 6.90 0.262 25 LNU48 24803.2 46.55 0.528 8 LNU46 14462.1 4.60 0.009 14 LNU8 25062.1 6.81 0.405 24 LNU63 24814.2 54.54 0.044 26 LNU48 24801.4 4.57 0.000 13 LNU8 25062.2 6.00 0.024 9 LNU63 24814.6 49.55 0.035 14 LNU48 24802.1 4.44 0.480 10 LNU8 25061.2 5.96 0.360 8 LNU63 24812.3 45.47 0.234 5 LNU48 24803.2 4.12 0.714 2 LNU94 24833.1 6.98 0.006 27 LNU63 24814.7 44.44 0.562 3 LNU63 24814.2 4.54 0.028 12 LNU94 24831.4 6.89 0.092 25 LNU7 25081.1 54.97 0.061 27 LNU63 24814.6 4.48 0.004 11 LNU94 24833.3 6.88 0.101 25 LNU7 25083.1 47.07 0.643 9 LNU63 24814.7 4.13 0.375 2 LNU94 24834.4 6.54 0.594 19 LNU7 25083.3 45.32 0.338 5 LNU7 25081.1 4.63 0.039 14 LNU96 25071.2 6.37 0.261 16 LNU8 25063.1 55.17 0.240 27 LNU7 25083.1 4.32 0.569 7 LNU96 25073.4 6.26 0.027 14 LNU8 25062.1 51.57 0.580 19 LNU8 25063.1 4.59 0.202 13 LNU96 25071.3 6.25 0.601 13 LNU8 25062.2 47.97 0.015 11 LNU8 25062.1 4.43 0.453 10 CONT. — 5.52 — 0 LNU8 25061.2 47.65 0.283 10 LNU8 25062.2 4.28 0.023 6 LNU10 25123.5 6.36 0.501 15 LNU94 24833.1 55.84 0.003 29 LNU8 25061.2 4.23 0.060 5 LNU122 25332.5 7.43 0.076 35 LNU94 24833.3 55.01 0.082 27 LNU94 24831.4 4.57 0.059 13 LNU122 25332.2 6.54 0.271 19 LNU94 24834.4 52.33 0.564 21 LNU94 24833.1 4.54 0.234 12 LNU122 25332.1 5.85 0.107 6 LNU94 24831.4 51.83 0.377 20 LNU94 24833.3 4.47 0.001 10 LNU125 25941.4 6.33 0.058 15 LNU96 25071.2 50.95 0.223 18 LNU94 24834.4 4.28 0.678 6 LNU125 25943.2 6.05 0.017 10 LNU96 25073.4 50.07 0.016 16 LNU96 25071.2 4.32 0.311 7 LNU178 14611.5 6.41 0.271 16 LNU96 25071.3 50.01 0.560 16 LNU96 25073.4 4.27 0.121 6 LNU178 14611.1 5.90 0.494 7 CONT. — 44.13 — 0 LNU96 25071.3 4.23 0.729 5 LNU178 14612.1 5.77 0.771 5 LNU10 25123.5 50.86 0.501 15 CONT. — 4.07 — 0 LNU234 25014.4 6.04 0.267 9 LNU122 25332.5 59.44 0.076 35 LNU10 25123.5 4.50 0.413 11 LNU236 25423.3 6.00 0.132 9 LNU122 25332.2 52.35 0.271 19 LNU122 25332.5 4.69 0.003 15 LNU236 25425.3 5.96 0.660 8 LNU122 25332.1 46.78 0.107 6 LNU122 25332.2 4.35 0.245 7 LNU236 25424.2 5.95 0.471 8 LNU125 25941.4 50.64 0.058 15 LNU122 25332.1 4.27 0.198 5 LNU236 25425.4 5.73 0.639 4 LNU125 25943.2 48.42 0.017 10 LNU125 25941.4 4.41 0.004 8 LNU236 25422.4 5.73 0.273 4 LNU178 14611.5 51.30 0.271 16 LNU125 25943.2 4.20 0.109 3 LNU25 14083.7 6.23 0.090 13 LNU178 14611.1 47.22 0.494 7 LNU178 14611.5 4.38 0.025 8 LNU25 14082.8 6.00 0.068 9 LNU178 14612.1 46.17 0.771 5 LNU178 14611.1 4.23 0.524 4 LNU271 25911.4 6.14 0.007 11 LNU234 25014.4 48.31 0.267 9 LNU234 25014.4 4.35 0.065 7 LNU278 25814.1 6.84 0.000 24 LNU236 25423.3 48.03 0.132 9 LNU236 25425.4 4.29 0.469 5 LNU278 25814.3 6.80 0.049 23 LNU236 25425.3 47.68 0.660 8 LNU236 25425.3 4.27 0.665 5 LNU278 25813.2 5.87 0.769 6 LNU236 25424.2 47.58 0.471 8 LNU236 25423.3 4.18 0.177 3 LNU278 25812.3 5.80 0.562 5 LNU236 25425.4 45.87 0.639 4 LNU25 14083.7 4.37 0.179 7 LNU278 25812.2 5.74 0.748 4 LNU236 25422.4 45.86 0.273 4 LNU25 14082.8 4.28 0.102 5 LNU43 14423.7 5.87 0.454 6 LNU25 14083.7 49.87 0.090 13 LNU267 25803.1 4.17 0.224 2 LNU43 14423.6 5.85 0.597 6 LNU25 14082.8 48.04 0.068 9 LNU271 25911.4 4.32 0.005 6 LNU45 25052.12 7.09 0.347 29 LNU271 25911.4 49.15 0.007 11 LNU271 25913.3 4.17 0.665 2 LNU45 25053.4 7.03 0.158 28 LNU278 25814.1 54.73 0.000 24 LNU278 25814.1 4.53 0.014 11 LNU45 25052.11 6.11 0.526 11 LNU278 25814.3 54.39 0.049 23 LNU278 25814.3 4.51 0.018 11 LNU45 25052.9 5.81 0.542 5 LNU278 25813.2 46.93 0.769 6 LNU278 25812.2 4.29 0.549 5 LNU67 25823.5 7.64 0.000 39 LNU278 25812.3 46.39 0.562 5 LNU278 25813.2 4.23 0.708 4 LNU67 25824.5 5.73 0.563 4 LNU278 25812.2 45.95 0.748 4 LNU278 25812.3 4.21 0.465 3 LNU67 25821.5 5.65 0.575 2 LNU43 14423.7 46.93 0.454 6 LNU43 14423.7 4.28 0.436 5 LNU9 25001.7 6.07 0.382 10 LNU43 14423.6 46.77 0.597 6 LNU43 14423.6 4.22 0.486 4 LNU9 25001.1 5.69 0.730 3 LNU45 25052.12 56.76 0.347 29 LNU45 25052.12 4.65 0.342 14 LNU9 25003.1 5.68 0.610 3 LNU45 25053.4 56.27 0.158 28 LNU45 25053.4 4.56 0.208 12 CONT. — 7.52 — 0 LNU45 25052.11 48.88 0.526 11 LNU45 25052.11 4.24 0.619 4 LNU10 25123.6 9.66 0.315 29 LNU45 25052.9 46.47 0.542 5 LNU45 25052.9 4.21 0.378 3 LNU10 25123.5 8.34 0.102 11 LNU67 25823.5 61.12 0.000 39 LNU67 25823.5 4.72 0.004 16 LNU157 24982.8 7.91 0.274 5 LNU67 25824.5 45.84 0.563 4 LNU67 25824.3 4.23 0.447 4 LNU168 24753.5 8.14 0.367 8 LNU67 25821.5 45.21 0.575 2 LNU9 25001.7 4.29 0.201 6 LNU173 25451.1 8.31 0.009 10 LNU9 25001.7 48.58 0.382 10 LNU9 25003.1 4.19 0.138 3 LNU173 25451.2 7.86 0.634 5 LNU9 25001.1 45.53 0.730 3 LNU9 25001.1 4.15 0.729 2 LNU178 14611.5 9.41 0.002 25 LNU9 25003.1 45.46 0.610 3 CONT. — 4.68 — 0 LNU178 14611.4 9.14 0.223 22 CONT. — 60.15 — 0 LNU10 25123.6 5.27 0.289 13 LNU178 14611.1 9.08 0.135 21 LNU10 25123.6 77.30 0.315 29 LNU10 25123.5 4.98 0.007 7 LNU184 25393.1 9.32 0.512 24 LNU10 25123.5 66.75 0.102 11 LNU157 24982.8 4.91 0.084 5 LNU184 25393.2 9.21 0.123 22 LNU157 24982.8 63.29 0.274 5 LNU168 24753.5 4.93 0.301 6 LNU184 25394.3 9.18 0.443 22 LNU168 24753.5 65.11 0.367 8 LNU173 25451.1 5.21 0.016 11 LNU184 25395.1 8.66 0.155 15 LNU173 25451.1 66.45 0.009 10 LNU173 25451.2 4.77 0.648 2 LNU230 25415.1 10.23 0.024 36 LNU173 25451.2 62.87 0.634 5 LNU178 14611.5 5.23 0.136 12 LNU230 25413.2 9.09 0.162 21 LNU178 14611.5 75.30 0.002 25 LNU178 14611.4 5.15 0.052 10 LNU230 25412.1 8.84 0.000 18 LNU178 14611.4 73.11 0.223 22 LNU178 14611.1 5.05 0.206 8 LNU230 25413.1 8.51 0.025 13 LNU178 14611.1 72.61 0.135 21 LNU184 25394.3 5.28 0.400 13 LNU230 25412.2 8.44 0.068 12 LNU184 25393.1 74.53 0.512 24 LNU184 25393.1 5.26 0.428 12 LNU236 25425.4 9.76 0.202 30 LNU184 25393.2 73.66 0.123 22 LNU184 25393.2 5.14 0.273 10 LNU236 25424.2 9.53 0.078 27 LNU184 25394.3 73.42 0.443 22 LNU184 25395.1 5.09 0.015 9 LNU236 25423.3 8.78 0.364 17 LNU184 25395.1 69.24 0.155 15 LNU230 25415.1 5.42 0.002 16 LNU236 25422.4 8.71 0.006 16 LNU230 25415.1 81.83 0.024 36 LNU230 25413.2 5.11 0.006 9 LNU24 24974.2 8.96 0.272 19 LNU230 25413.2 72.72 0.162 21 LNU230 25412.1 5.07 0.001 8 LNU24 24971.2 8.70 0.001 16 LNU230 25412.1 70.74 0.000 18 LNU230 25413.1 4.97 0.028 6 LNU24 24971.3 8.53 0.547 13 LNU230 25413.1 68.11 0.025 13 LNU230 25412.2 4.97 0.186 6 LNU24 24972.1 8.05 0.085 7 LNU230 25412.2 67.54 0.068 12 LNU236 25425.4 5.38 0.204 15 LNU24 24971.4 7.76 0.788 3 LNU236 25425.4 78.05 0.202 30 LNU236 25424.2 5.33 0.121 14 LNU263 25794.8 9.47 0.222 26 LNU236 25424.2 76.22 0.078 27 LNU236 25423.3 5.08 0.329 9 LNU276 25433.3 9.55 0.001 27 LNU236 25423.3 70.24 0.364 17 LNU236 25422.4 4.95 0.044 6 LNU276 25431.1 7.87 0.282 5 LNU236 25422.4 69.67 0.006 16 LNU24 24971.2 5.23 0.032 12 LNU279 25481.3 9.22 0.414 23 LNU24 24974.2 71.68 0.272 19 LNU24 24974.2 5.09 0.352 9 LNU279 25481.4 8.87 0.167 18 LNU24 24971.2 69.57 0.001 16 LNU24 24971.3 5.03 0.556 8 LNU279 25481.5 8.81 0.413 17 LNU24 24971.3 68.22 0.547 13 LNU24 24972.1 4.81 0.229 3 LNU36 25562.3 7.66 0.786 2 LNU24 24972.1 64.42 0.085 7 LNU24 24971.4 4.80 0.482 3 LNU36 25562.7 7.66 0.594 2 LNU24 24971.4 62.06 0.788 3 LNU263 25794.8 5.31 0.121 14 LNU53 25674.1 9.58 0.175 27 LNU263 25794.8 75.78 0.222 26 LNU276 25433.3 5.25 0.002 12 LNU53 25674.2 7.84 0.722 4 LNU276 25433.3 76.41 0.001 27 LNU276 25431.1 4.81 0.282 3 LNU53 25674.6 7.72 0.545 3 LNU276 25431.1 62.93 0.282 5 LNU279 25481.4 5.08 0.321 9 LNU56 24693.1 8.44 0.356 12 LNU279 25481.3 73.77 0.414 23 LNU279 25481.3 5.02 0.552 7 LNU56 24694.1 8.33 0.056 11 LNU279 25481.4 70.96 0.167 18 LNU279 25481.5 5.01 0.447 7 LNU56 24693.2 7.76 0.556 3 LNU279 25481.5 70.48 0.413 17 LNU36 25562.3 4.96 0.429 6 LNU73 25755.1 9.11 0.194 21 LNU36 25562.3 61.29 0.786 2 LNU53 25674.1 5.35 0.188 14 LNU73 25751.1 8.87 0.641 18 LNU36 25562.7 61.26 0.594 2 LNU53 25674.2 4.85 0.112 4 LNU73 25754.2 8.51 0.642 13 LNU53 25674.1 76.62 0.175 27 LNU53 25674.6 4.85 0.235 4 LNU73 25751.8 8.46 0.566 12 LNU53 25674.2 62.69 0.722 4 LNU56 24693.1 5.02 0.358 7 LNU73 25751.9 8.14 0.255 8 LNU53 25674.6 61.73 0.545 3 LNU56 24694.1 4.95 0.147 6 LNU9 25001.1 9.43 0.119 25 LNU56 24693.1 67.51 0.356 12 LNU73 25751.1 5.16 0.600 10 LNU9 25001.7 9.08 0.159 21 LNU56 24694.1 66.68 0.056 11 LNU73 25755.1 5.13 0.188 10 LNU9 25001.2 8.80 0.315 17 LNU56 24693.2 62.11 0.556 3 LNU73 25754.2 5.05 0.562 8 LNU9 25001.3 8.59 0.527 14 LNU73 25755.1 72.87 0.194 21 LNU73 25751.8 5.02 0.539 7 CONT. — 5.46 — 0 LNU73 25751.1 70.95 0.641 18 LNU73 25751.9 4.87 0.323 4 LNU131 14005.2 8.63 0.000 58 LNU73 25754.2 68.05 0.642 13 LNU9 25001.1 5.27 0.006 13 LNU131 14005.5 7.70 0.000 41 LNU73 25751.8 67.65 0.566 12 LNU9 25001.7 5.23 0.108 12 LNU131 14002.15 5.68 0.675 4 LNU73 25751.9 65.14 0.255 8 LNU9 25001.2 5.00 0.381 7 LNU135 26203.1 6.47 0.756 18 LNU9 25001.1 75.41 0.119 25 LNU9 25001.3 4.93 0.552 5 LNU135 26204.2 6.39 0.071 17 LNU9 25001.7 72.60 0.159 21 CONT. — 3.89 — 0 LNU135 26203.4 6.30 0.740 15 LNU9 25001.2 70.42 0.315 17 LNU131 14005.2 4.95 0.001 27 LNU135 26203.6 5.91 0.651 8 LNU9 25001.3 68.74 0.527 14 LNU131 14005.5 4.66 0.000 20 LNU135 26203.3 5.59 0.723 2 CONT. — 43.36 — 0 LNU135 26203.4 4.17 0.763 7 LNU161 14552.9 5.58 0.793 2 LNU131 14005.2 69.03 0.000 59 LNU135 26204.2 4.15 0.173 7 LNU173 25451.2 7.12 0.405 30 LNU131 14005.5 61.62 0.000 42 LNU135 26203.6 4.04 0.754 4 LNU173 25451.5 5.78 0.563 6 LNU131 14002.15 45.46 0.614 5 LNU173 25451.2 4.44 0.465 14 LNU181 25771.8 7.22 0.385 32 LNU135 26203.1 51.73 0.746 19 LNU181 25771.8 4.49 0.391 15 LNU181 25771.6 6.86 0.005 25 LNU135 26204.2 51.12 0.062 18 LNU181 25771.6 4.32 0.006 11 LNU181 25774.1 6.52 0.018 19 LNU135 26203.4 50.44 0.727 16 LNU181 25771.5 4.21 0.573 8 LNU181 25771.5 6.38 0.548 17 LNU135 26203.6 47.26 0.621 9 LNU181 25774.1 4.10 0.130 5 LNU184 25393.2 7.56 0.000 38 LNU135 26203.3 44.70 0.629 3 LNU184 25393.2 4.54 0.000 17 LNU184 25394.1 7.46 0.238 36 LNU161 14552.9 44.61 0.713 3 LNU184 25394.1 4.52 0.195 16 LNU184 25393.1 6.68 0.061 22 LNU173 25451.2 56.96 0.397 31 LNU184 25393.3 4.34 0.530 11 LNU184 25393.3 6.64 0.595 21 LNU173 25451.5 46.25 0.512 7 LNU184 25393.1 4.32 0.096 11 LNU184 25394.3 6.51 0.645 19 LNU181 25771.8 57.77 0.377 33 LNU184 25394.3 4.27 0.603 10 LNU184 25395.1 6.01 0.471 10 LNU181 25771.6 54.86 0.004 27 LNU184 25395.1 3.96 0.799 2 LNU224 25872.3 9.03 0.019 65 LNU181 25774.1 52.14 0.014 20 LNU224 25872.3 5.01 0.045 29 LNU224 25874.4 8.06 0.136 47 LNU181 25771.5 51.03 0.532 18 LNU224 25874.1 4.62 0.275 19 LNU224 25874.1 7.70 0.317 41 LNU184 25393.2 60.48 0.000 39 LNU224 25874.4 4.61 0.105 18 LNU224 25872.2 7.18 0.359 31 LNU184 25394.1 59.65 0.232 38 LNU224 25872.2 4.45 0.255 14 LNU224 25871.3 5.78 0.451 6 LNU184 25393.1 53.47 0.055 23 LNU246 25744.3 4.64 0.491 19 LNU246 25744.3 7.98 0.492 46 LNU184 25394.3 52.09 0.633 20 LNU246 25744.2 4.64 0.043 19 LNU246 25744.2 7.83 0.167 43 LNU184 25393.3 50.56 0.719 17 LNU246 25744.4 4.60 0.531 18 LNU246 25744.4 7.70 0.539 41 LNU184 25395.1 48.06 0.440 11 LNU246 25743.1 4.44 0.177 14 LNU246 25743.1 6.94 0.175 27 LNU224 25872.3 72.21 0.019 67 LNU246 25743.2 4.24 0.017 9 LNU246 25743.2 6.60 0.006 21 LNU224 25874.4 64.48 0.133 49 LNU250 25591.1 4.80 0.006 23 LNU250 25591.1 8.34 0.140 53 LNU224 25874.1 61.56 0.311 42 LNU250 25592.2 4.41 0.001 13 LNU250 25592.2 6.69 0.003 22 LNU224 25872.2 57.46 0.351 33 LNU260 26404.1 4.10 0.473 5 LNU260 26404.1 6.08 0.526 11 LNU224 25871.3 46.25 0.391 7 LNU276 25433.6 4.57 0.306 17 LNU260 26403.1 5.88 0.523 8 LNU246 25744.3 63.80 0.486 47 LNU276 25433.5 4.20 0.487 8 LNU276 25433.6 7.47 0.273 37 LNU246 25744.2 62.63 0.163 44 LNU279 25481.3 4.68 0.457 20 LNU276 25433.5 6.51 0.490 19 LNU246 25744.4 61.63 0.533 42 LNU279 25484.3 4.60 0.331 18 LNU276 25433.3 5.80 0.607 6 LNU246 25743.2 52.80 0.005 22 LNU279 25481.2 3.96 0.708 2 LNU279 25484.3 7.86 0.232 44 LNU246 25743.1 51.76 0.010 19 LNU3 26124.3 4.05 0.307 4 LNU279 25481.3 7.80 0.383 43 LNU250 25591.1 66.75 0.137 54 LNU33 25553.3 4.15 0.416 7 LNU279 25481.2 6.22 0.206 14 LNU250 25592.2 53.50 0.002 23 LNU53 25674.5 4.05 0.348 4 LNU279 25481.5 6.02 0.769 10 LNU260 26404.1 48.66 0.501 12 LNU56 24694.2 4.01 0.359 3 LNU3 26122.2 5.76 0.546 5 LNU260 26403.1 47.04 0.484 8 CONT. — 4.57 — 0 LNU3 26124.3 5.71 0.636 4 LNU276 25433.6 59.76 0.267 38 LNU130 24912.7 5.24 0.000 15 LNU33 25553.3 6.36 0.406 16 LNU276 25433.5 52.07 0.476 20 LNU130 24913.5 4.81 0.452 5 LNU33 25552.2 5.73 0.453 5 LNU276 25433.3 46.39 0.563 7 LNU130 24911.7 4.79 0.709 5 LNU53 25674.5 6.02 0.129 10 LNU279 25484.3 62.91 0.228 45 LNU136 14515.1 5.09 0.087 12 LNU56 24694.2 5.79 0.346 6 LNU279 25481.3 62.39 0.377 44 LNU142 27541.1 4.78 0.662 5 CONT. — 7.19 — 0 LNU279 25481.2 49.74 0.186 15 LNU15 14123.13 4.85 0.095 6 LNU119 26142.8 7.51 0.405 4 LNU279 25481.5 48.15 0.752 11 LNU15 14123.11 4.83 0.046 6 LNU130 24912.7 8.81 0.058 23 LNU3 26122.2 46.10 0.489 6 LNU185 26475.1 4.91 0.486 8 LNU130 24913.5 7.84 0.354 9 LNU3 26124.3 45.68 0.578 5 LNU185 26474.2 4.77 0.091 4 LNU130 24911.7 7.63 0.793 6 LNU33 25553.3 50.90 0.388 17 LNU212 25834.5 4.87 0.163 7 LNU130 24913.6 7.54 0.613 5 LNU33 25552.2 45.87 0.382 6 LNU212 25834.1 4.85 0.527 6 LNU136 14515.1 8.58 0.046 19 LNU53 25674.5 48.16 0.103 11 LNU216 25985.4 4.95 0.714 8 LNU142 27541.1 8.08 0.487 12 LNU56 24694.2 46.36 0.287 7 LNU216 25982.1 4.72 0.350 3 LNU142 27545.1 7.62 0.787 6 CONT. — 57.54 — 0 LNU216 25982.2 4.65 0.766 2 LNU142 27546.1 7.55 0.280 5 LNU119 26142.8 60.06 0.405 4 LNU228 26222.4 4.93 0.168 8 LNU15 14123.13 8.21 0.064 14 LNU130 24912.7 70.52 0.058 23 LNU228 26224.7 4.76 0.623 4 LNU15 14123.11 7.71 0.257 7 LNU130 24913.5 62.68 0.354 9 LNU241 26232.4 4.79 0.104 5 LNU185 26475.1 8.28 0.371 15 LNU130 24911.7 61.01 0.793 6 LNU241 26233.2 4.77 0.290 4 LNU185 26474.2 7.75 0.352 8 LNU130 24913.6 60.30 0.613 5 LNU277 25845.1 4.73 0.691 4 LNU212 25834.5 8.45 0.003 18 LNU136 14515.1 68.61 0.046 19 LNU280 26162.1 5.13 0.547 12 LNU212 25834.1 7.98 0.668 11 LNU142 27541.1 64.66 0.487 12 LNU280 26162.7 4.79 0.255 5 LNU216 25985.4 8.64 0.625 20 LNU142 27545.1 60.95 0.787 6 LNU55 26015.1 4.82 0.304 5 LNU216 25982.1 7.69 0.532 7 LNU142 27546.1 60.40 0.280 5 LNU81 26034.3 5.23 0.040 14 LNU216 25982.2 7.54 0.539 5 LNU15 14123.13 65.70 0.064 14 CONT. — 4.91 — 0 LNU228 26222.4 8.01 0.037 11 LNU15 14123.11 61.64 0.257 7 LNU119 26141.1 5.35 0.525 9 LNU228 26224.7 7.58 0.588 5 LNU185 26475.1 66.26 0.371 15 LNU119 26142.8 5.22 0.246 6 LNU241 26233.2 7.94 0.271 10 LNU185 26474.2 61.98 0.352 8 LNU130 24914.5 5.30 0.068 8 LNU274 26265.1 7.38 0.559 3 LNU212 25834.5 67.62 0.003 18 LNU136 14515.1 5.19 0.363 6 LNU277 25845.1 8.19 0.506 14 LNU212 25834.1 63.81 0.668 11 LNU142 27541.2 5.19 0.243 6 LNU280 26162.1 9.03 0.532 26 LNU216 25985.4 69.11 0.625 20 LNU142 27541. 5.18 0.641 6 LNU280 26162.7 7.81 0.372 9 LNU216 25982.1 61.50 0.532 7 LNU142 27545.1 5.11 0.039 4 LNU55 26015.1 7.57 0.495 5 LNU216 25982.2 60.31 0.539 5 LNU15 14123.11 5.64 0.450 15 LNU55 26015.3 7.33 0.676 2 LNU228 26222.4 64.07 0.037 11 LNU15 14122.8 5.43 0.709 11 LNU81 26034.3 9.24 0.001 28 LNU228 26224.7 60.67 0.588 5 LNU15 14123.13 5.36 0.081 9 CONT. — 8.21 — 0 LNU241 26233.2 63.55 0.271 10 LNU212 25834.5 5.27 0.020 7 LNU119 26142.8 9.21 0.257 12 LNU274 26265.1 59.07 0.559 3 LNU212 25834.1 5.09 0.469 4 LNU119 26141.1 8.81 0.725 7 LNU277 25845.1 65.53 0.506 14 LNU212 25834.4 5.04 0.481 3 LNU130 24914.5 9.08 0.160 11 LNU280 26162.1 72.23 0.532 26 LNU216 25984.6 5.11 0.290 4 LNU130 24913.5 8.41 0.792 2 LNU55 26015.1 60.59 0.495 5 LNU216 25984.1 5.11 0.459 4 LNU136 14515.1 8.81 0.488 7 LNU55 26015.3 58.66 0.676 2 LNU228 26224.7 5.49 0.069 12 LNU142 27541.1 8.99 0.680 10 LNU81 26034.3 73.89 0.001 28 LNU228 26222.1 5.32 0.001 8 LNU142 27541.2 8.81 0.265 7 CONT. — 65.65 — 0 LNU229 26111.5 5.30 0.002 8 LNU142 27545.1 8.76 0.036 7 LNU119 26142.8 73.65 0.257 12 LNU241 26232.4 5.31 0.438 8 LNU149 26174.7 8.81 0.799 7 LNU130 24914.5 72.61 0.160 11 LNU274 26262.2 5.10 0.464 4 LNU15 14123.11 10.26 0.454 25 LNU130 24913.5 67.25 0.792 2 LNU277 25842.3 5.28 0.524 7 LNU15 14122.8 10.12 0.624 23 LNU136 14515.1 70.47 0.488 7 LNU280 26164.4 5.21 0.005 6 LNU15 14123.13 9.22 0.424 12 LNU142 27541.1 71.91 0.680 10 LNU280 26164.3 5.11 0.061 4 LNU212 25834.5 9.20 0.260 12 LNU142 27541.2 70.52 0.265 7 LNU280 26162.1 5.10 0.346 4 LNU212 25834.4 8.59 0.703 5 LNU142 27545.1 70.07 0.036 7 LNU81 26031.10 5.59 0.339 14 LNU216 25984.1 9.00 0.597 10 LNU149 26174.7 70.46 0.799 7 LNU81 26034.3 5.12 0.770 4 LNU216 25982.2 8.73 0.147 6 LNU15 14123.11 82.11 0.454 25 LNU81 26034.2 5.12 0.022 4 LNU216 25984.6 8.55 0.486 4 LNU15 14122.8 80.97 0.624 23 CONT. 4.203 — 0.0 LNU228 26222.1 9.79 0.004 19 LNU15 14123.13 73.80 0.424 12 LNU61 26134.4 4.780 0.02 13.7 LNU228 26224.7 9.60 0.018 17 LNU212 25834.5 73.62 0.260 12 CONT. — 4.203 — 0.0 LNU229 26111.5 8.83 0.421 8 LNU212 25834.4 68.74 0.703 5 LNU134 29191.3 4.344 <0.8 3.3 LNU241 26232.4 9.50 0.384 16 LNU216 25984.1 71.97 0.597 10 LNU134 29191.6 4.524 <0.3 7.6 LNU274 26262.2 8.45 0.409 3 LNU216 25982.2 69.80 0.147 6 LNU134 29194.1 4.365 <0.7 3.8 LNU277 25842.3 9.21 0.560 12 LNU216 25984.6 68.39 0.486 4 LNU198 27735.4 4.406 <0.7 4.8 LNU280 26164.4 9.50 0.000 16 LNU228 26222.1 78.34 0.004 19 LNU200 27992.2 4.704 <0.1 11.9 LNU280 26162.1 8.65 0.122 5 LNU228 26224.7 76.83 0.018 17 LNU200 27992.3 4.608 <0.3 9.6 LNU81 26031.10 10.53 0.247 28 LNU229 26111.5 70.61 0.421 8 LNU200 27993.4 4.735 <0.1 12.6 LNU81 26034.3 8.79 0.743 7 LNU241 26232.4 76.03 0.384 16 LNU200 27994.3 4.378 <0.8 4.1 LNU81 26031.9 8.48 0.768 3 LNU274 26262.2 67.61 0.409 3 LNU244 28013.6 4.584 <0.3 9.1 CONT. 5.508 — 0.0 LNU277 25842.3 73.68 0.560 12 LNU244 28013.8 4.635 <0.3 10.3 LNU61 26134.4 6.634 0.045 20.5 LNU280 26164.4 76.02 0.000 16 LNU244 28014.4 4.673 <0.1 11.2 LNU61 26135.3 5.827 0.55 5.8 LNU280 26162.1 69.21 0.122 5 LNU244 28015.1 4.628 <0.3 10.1 CONT. — 5.508 — 0.0 LNU81 26031.10 84.26 0.247 28 LNU262 27591.3 4.517 <0.3 7.5 LNU123 27722.4 5.740 <0.8 4.2 LNU81 26034.3 70.32 0.743 7 LNU262 27591.7 4.740 <0.1 12.8 LNU134 29191.3 5.789 <0.8 5.1 LNU81 26031.9 67.84 0.768 3 LNU262 27593.1 4.860 <0.1 15.6 LNU134 29191.6 6.647 <0.1 20.7 CONT. 44.061 — 0.0 LNU262 27593.6 4.849 <0.1 15.4 LNU134 29194.1 6.208 <0.4 12.7 LNU61 26134.4 53.071 0.045 20.5 LNU262 27595.2 4.884 <0.1 16.2 LNU198 27735.4 6.147 <0.4 11.6 LNU61 26135.3 46.614 0.55 5.8 LNU266 27931.5 4.544 <0.3 8.1 LNU200 27992.2 6.852 <0.1 24.4 CONT. — 44.061 — 0.0 LNU266 27932.1 4.312 <0.8 2.6 LNU200 27992.3 6.540 <0.1 18.7 LNU123 27722.4 45.924 <0.7 4.2 LNU266 27935.3 4.632 <0.3 10.2 LNU200 27993.4 6.516 <0.1 18.3 LNU134 29191.6 53.174 <0.1 20.7 LNU266 27935.4 4.449 <0.7 5.8 LNU200 27994.3 6.021 <0.4 9.3 LNU134 29194.1 49.666 <0.3 12.7 LNU29 27652.2 4.297 <0.8 2.2 LNU244 28013.6 6.619 <0.1 20.2 LNU198 27735.4 49.176 <0.7 11.6 LNU29 27653.1 4.758 <0.1 13.2 LNU244 28013.8 6.593 <0.1 19.7 LNU200 27992.2 54.815 <0.1 24.4 LNU29 27654.1 4.748 <0.1 13.0 LNU244 28014.4 6.854 <0.1 24.4 LNU200 27992.3 52.322 <0.1 18.7 LNU29 27655.1 4.751 <0.1 13.0 LNU244 28015.1 6.623 <0.1 20.3 LNU200 27993.4 52.124 <0.1 18.3 LNU32 29252.6 4.427 <0.3 5.3 LNU262 27591.3 6.548 <0.1 18.9 LNU200 27994.3 48.167 <0.7 9.3 LNU51 27612.2 4.681 <0.1 11.4 LNU262 27591.7 6.654 <0.1 20.8 LNU244 28013.6 52.951 <0.1 20.2 LNU51 27614.4 4.482 <0.3 6.6 LNU262 27593.1 7.392 <0.1 34.2 LNU244 28013.8 52.747 <0.1 19.7 LNU51 27616.1 4.677 <0.3 11.3 LNU262 27593.6 7.160 <0.1 30.0 LNU244 28014.4 54.828 <0.1 24.4 LNU58 27673.4 4.505 <0.3 7.2 LNU262 27595.2 7.217 <0.1 31.0 LNU244 28015.1 52.986 <0.1 20.3 CONT. 8252.24 2.097 0.0 LNU266 27931.5 6.158 <0.4 11.8 LNU262 27591.3 52.382 <0.1 18.9 LNU89 25325.2 2.217 0.7 5.7 LNU266 27932.1 5.966 <0.4 8.3 LNU262 27591.7 53.232 <0.1 20.8 LNU266 27935.3 6.563 <0.1 19.2 LNU262 27593.1 59.137 <0.1 34.2 LNU266 27935.4 6.305 <0.4 14.5 LNU262 27593.6 57.278 <0.1 30.0 LNU29 27653.1 7.013 <0.1 27.3 LNU262 27595.2 57.740 <0.1 31.0 LNU29 27654.1 6.500 <0.1 18.0 LNU266 27931.5 49.265 <0.7 11.8 LNU29 27655.1 6.526 <0.1 18.5 LNU266 27932.1 47.729 <0.7 8.3 LNU32 29251.1 5.912 <0.8 7.3 LNU266 27935.3 52.505 <0.1 19.2 LNU32 29252.6 6.123 <0.4 11.2 LNU266 27935.4 50.439 <0.3 14.5 LNU51 27612.2 6.630 <0.1 20.4 LNU29 27653.1 56.105 <0.1 27.3 LNU51 27614.4 6.359 <0.4 15.5 LNU29 27654.1 51.998 <0.1 18.0 LNU51 27616.1 6.922 <0.1 25.7 LNU29 27655.1 52.211 <0.1 18.5 LNU58 27673.2 5.906 <0.8 7.2 LNU32 29251.1 47.296 <0.7 7.3 LNU58 27673.4 6.527 <0.1 18.5 LNU32 29252.6 48.987 <0.7 11.2 LNU51 27612.2 53.044 <0.1 20.4 LNU51 27614.4 50.868 <0.1 15.5 LNU51 27616.1 55.376 <0.1 25.7 LNU58 27673.2 47.248 <0.3 7.2 LNU58 27673.4 52.219 <0.15 18.5 CONT. 8252.24 10.791 0.0 LNU89 25325.1 11.960 0.3 10.8 LNU89 25325.2 11.480 0.54 6.4 Table 83. “CONT.”—Control; “Ave.”—Average; “% Incr.” = % increment.

The genes listed in Table 84 improved plant NUE when grown at standard nitrogen concentration levels. These genes produced larger photosynthetic areas as it can be observed by their larger leaf blade area and leaf petiole length. The genes were cloned under the regulation of a constitutive (At6669) and root preferred promoter (RootP). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant

TABLE 84 Genes showing improved photosynthetic capacity at standard nitrogen growth conditions Leaf Blade Area Leaf Petiole Leaf Number [cm²] Length [cm] Gene Event P- % Gene Event P- % Gene Event P- % Name # Ave. Value incr. Name # Ave. Value incr. Name # Ave. Value incr. CONT. — 10.49 — 0 CONT. — 0.64 — 0 CONT. — 0.76 — 0 LNU100 14471.4 11.25 0.262 7 LNU100 14471.4 0.81 0.306 28 LNU100 14471.4 0.88 0.214 16 LNU100 14473.3 11.13 0.024 6 LNU100 14474.3 0.77 0.003 21 LNU100 14473.3 0.87 0.010 14 LNU100 14474.3 11.13 0.024 6 LNU100 14473.3 0.77 0.117 20 LNU100 14472.2 0.85 0.002 11 LNU100 14472.2 10.75 0.472 2 LNU100 14472.2 0.75 0.256 17 LNU100 14474.3 0.84 0.102 10 LNU100 14474.4 10.69 0.639 2 LNU104 25032.2 0.91 0.059 43 LNU104 25033.1 0.96 0.055 26 LNU104 25032.2 12.13 0.001 16 LNU104 25033.1 0.89 0.159 39 LNU104 25032.2 0.95 0.179 25 LNU104 25034.1 11.00 0.048 5 LNU104 25032.1 0.88 0.076 38 LNU104 25033.3 0.90 0.002 18 LNU104 25032.1 10.94 0.631 4 LNU104 25033.3 0.84 0.007 31 LNU104 25032.1 0.89 0.157 17 LNU104 25033.3 10.94 0.015 4 LNU104 25034.1 0.70 0.146 10 LNU104 25034.1 0.80 0.437 4 LNU104 25033.1 10.69 0.639 2 LNU106 14482.3 0.79 0.371 24 LNU106 14482.3 0.90 0.441 19 LNU106 14483.5 11.06 0.115 5 LNU106 14483.5 0.78 0.140 22 LNU106 14483.5 0.90 0.000 17 LNU106 14482.3 10.88 0.329 4 LNU106 14483.2 0.76 0.264 20 LNU106 14483.2 0.83 0.043 8 LNU106 14483.2 10.75 0.610 2 LNU106 14481.1 0.66 0.416 3 LNU114 25041.1 0.99 0.000 29 LNU114 25041.1 11.94 0.000 14 LNU114 25041.1 0.86 0.000 35 LNU114 25042.1 0.85 0.000 12 LNU114 25041.2 11.00 0.048 5 LNU114 25042.1 0.77 0.122 21 LNU114 25041.2 0.84 0.250 10 LNU114 25042.1 10.69 0.222 2 LNU114 25041.2 0.70 0.018 9 LNU155 14525.1 0.85 0.540 12 LNU213 24653.2 11.50 0.090 10 LNU155 14525.6 0.78 0.126 23 LNU155 14525.6 0.85 0.231 11 LNU213 24653.1 10.75 0.472 2 LNU155 14525.1 0.71 0.598 12 LNU213 24653.2 1.00 0.000 32 LNU218 24781.2 11.00 0.486 5 LNU213 24653.2 0.88 0.000 39 LNU213 24652.4 0.88 0.468 15 LNU218 24781.1 10.81 0.591 3 LNU213 24652.4 0.83 0.472 31 LNU213 24653.1 0.83 0.200 8 LNU218 24781.7 10.75 0.230 2 LNU213 24653.1 0.74 0.000 16 LNU218 24781.7 0.91 0.091 20 LNU23 25163.5 11.06 0.401 5 LNU213 24654.4 0.68 0.754 7 LNU218 24781.1 0.89 0.004 16 LNU28 25171.1 10.88 0.688 4 LNU218 24781.1 0.82 0.211 29 LNU218 24781.2 0.85 0.001 11 LNU28 25171.2 10.88 0.102 4 LNU218 24781.7 0.80 0.254 25 LNU23 25163.5 0.91 0.234 19 LNU4 25134.1 11.25 0.262 7 LNU218 24781.2 0.70 0.232 11 LNU23 25163.6 0.83 0.193 9 LNU4 25134.3 11.06 0.282 5 LNU23 25163.5 0.90 0.028 41 LNU28 25171.2 0.89 0.143 16 LNU4 25133.3 10.94 0.015 4 LNU23 25163.6 0.70 0.546 9 LNU28 25171.1 0.80 0.064 5 LNU4 25134.2 10.69 0.639 2 LNU28 25171.2 0.81 0.201 28 LNU28 25171.4 0.79 0.610 4 LNU40 24794.4 10.88 0.102 4 LNU28 25174.3 0.78 0.071 23 LNU28 25174.3 0.78 0.381 2 LNU46 14464.4 11.69 0.196 11 LNU28 25171.1 0.72 0.240 13 LNU4 25134.1 0.89 0.116 16 LNU46 14463.1 11.31 0.371 8 LNU28 25174.5 0.68 0.508 7 LNU4 25133.3 0.86 0.225 12 LNU46 14462.5 11.19 0.079 7 LNU28 25171.4 0.65 0.790 3 LNU4 25134.3 0.83 0.476 9 LNU48 24802.2 12.00 0.182 14 LNU4 25134.1 0.86 0.062 35 LNU4 25134.2 0.80 0.164 4 LNU48 24801.4 11.25 0.000 7 LNU4 25133.3 0.77 0.000 22 LNU40 24794.3 0.88 0.322 15 LNU48 24802.1 11.13 0.001 6 LNU4 25134.3 0.76 0.419 20 LNU40 24794.4 0.86 0.221 13 LNU63 24812.2 11.06 0.282 5 LNU4 25131.1 0.69 0.563 9 LNU40 24792.1 0.81 0.029 6 LNU63 24814.2 10.94 0.483 4 LNU4 25134.2 0.69 0.404 8 LNU46 14463.1 0.92 0.307 21 LNU7 25083.1 11.13 0.024 6 LNU40 24794.3 0.83 0.013 30 LNU46 14464.4 0.92 0.125 21 LNU7 25082.2 11.00 0.384 5 LNU40 24794.4 0.78 0.248 22 LNU46 14462.5 0.89 0.001 17 LNU7 25081.1 10.81 0.060 3 LNU40 24792.1 0.70 0.011 10 LNU46 14462.1 0.80 0.321 4 LNU7 25082.7 10.69 0.473 2 LNU40 24792.2 0.67 0.582 6 LNU48 24801.4 0.95 0.000 25 LNU8 25062.2 10.88 0.647 4 LNU46 14463.1 0.83 0.288 30 LNU48 24802.2 0.92 0.214 21 LNU8 25063.1 10.75 0.748 2 LNU46 14464.4 0.83 0.258 30 LNU48 24802.1 0.90 0.216 17 LNU8 25063.6 10.69 0.639 2 LNU46 14462.5 0.82 0.000 29 LNU63 24814.2 0.87 0.489 14 LNU94 24833.3 11.13 0.001 6 LNU46 14462.1 0.75 0.214 17 LNU63 24812.2 0.83 0.441 9 LNU94 24831.4 11.00 0.048 5 LNU48 24801.4 0.93 0.004 46 LNU63 24811.2 0.80 0.686 5 LNU94 24834.4 10.69 0.473 2 LNU48 24802.1 0.81 0.017 28 LNU7 25081.1 0.90 0.013 17 LNU96 25071.3 11.06 0.004 5 LNU48 24802.2 0.81 0.000 27 LNU7 25083.3 0.84 0.415 10 LNU96 25073.3 11.03 0.530 5 LNU63 24814.2 0.81 0.376 28 LNU7 25083.1 0.82 0.009 8 LNU96 25073.4 10.69 0.222 2 LNU63 24812.2 0.72 0.265 13 LNU8 25063.6 0.85 0.045 12 CONT. — 11.17 — 0 LNU63 24814.3 0.71 0.507 12 LNU8 25062.2 0.80 0.132 5 LNU124 14501.1 11.56 0.231 4 LNU63 24811.2 0.68 0.730 7 LNU94 24831.4 0.86 0.027 12 LNU132 14103.9 11.38 0.297 2 LNU7 25081.1 0.78 0.003 22 LNU94 24834.4 0.84 0.002 9 LNU140 14112.7 11.38 0.552 2 LNU7 25083.1 0.76 0.003 20 LNU94 24833.3 0.79 0.598 4 LNU37 14064.7 11.56 0.010 4 LNU7 25083.3 0.69 0.445 9 LNU96 25071.3 0.81 0.395 7 LNU72 24962.3 11.69 0.002 5 LNU7 25082.2 0.65 0.268 3 LNU96 25073.4 0.81 0.464 7 LNU82 24823.1 11.75 0.221 5 LNU8 25063.6 0.77 0.240 21 LNU96 25073.3 0.81 0.763 6 LNU84 25621.2 11.38 0.297 2 LNU8 25062.2 0.72 0.202 13 CONT. — 0.84 — 0 LNU87 24712.4 11.44 0.761 2 LNU8 25063.1 0.68 0.036 7 LNU5 14042.7 0.91 0.264 8 LNU98 25762.2 11.75 0.045 5 LNU8 25061.2 0.68 0.124 6 LNU72 24962.3 0.91 0.559 8 CONT. — 10.96 — 0 LNU94 24833.3 0.79 0.280 25 LNU87 24714.3 0.87 0.753 3 LNU124 14504.5 11.38 0.076 4 LNU94 24834.4 0.75 0.015 19 LNU98 25763.2 0.86 0.757 2 LNU148 25685.6 11.81 0.567 8 LNU94 24831.4 0.74 0.005 17 CONT. — 0.76 — 0 LNU148 25685.2 11.63 0.140 6 LNU94 24833.1 0.71 0.624 11 LNU113 25631.1 0.92 0.325 20 LNU148 25683.2 11.19 0.459 2 LNU96 25073.3 0.75 0.357 17 LNU113 25631.3 0.85 0.570 11 LNU37 14064.7 11.25 0.198 3 LNU96 25071.3 0.71 0.238 12 LNU124 14504.5 0.84 0.388 11 LNU5 14043.9 11.19 0.603 2 LNU96 25073.4 0.67 0.521 6 LNU132 14102.9 0.86 0.489 12 LNU68 14034.13 11.56 0.092 6 CONT. — 0.92 — 0 LNU140 14115.1 0.78 0.771 2 LNU68 14033.9 11.31 0.562 3 LNU148 25685.6 0.97 0.438 6 LNU148 25685.1 0.83 0.065 8 LNU68 14034.1 11.31 0.641 3 LNU5 14042.7 1.01 0.003 9 LNU148 25683.2 0.79 0.454 3 LNU71 25852.5 11.75 0.475 7 LNU72 24962.3 0.99 0.393 8 LNU287 24674.3 0.81 0.628 7 LNU71 25851.4 11.25 0.269 3 LNU98 25763.2 0.98 0.024 7 LNU37 14064.7 0.97 0.300 27 LNU74 25441.2 11.56 0.018 6 CONT. — 0.82 — 0 LNU37 14064.6 0.93 0.434 21 LNU74 25444.1 11.38 0.127 4 LNU113 25631.3 1.00 0.210 23 LNU5 14043.9 0.81 0.406 6 LNU74 25443.2 11.25 0.443 3 LNU113 25631.1 0.98 0.043 19 LNU5 14043.7 0.78 0.587 2 LNU87 24712.1 11.25 0.665 3 LNU124 14504.5 0.91 0.218 11 LNU65 24703.6 0.89 0.001 17 CONT. — 11.68 — 0 LNU132 14102.9 0.89 0.737 9 LNU65 24702.3 0.82 0.643 8 LNU117 25931.4 12.13 0.429 4 LNU148 25685.1 0.97 0.016 18 LNU68 14034.13 0.90 0.525 18 LNU117 25933.3 12.13 0.281 4 LNU148 25685.2 0.91 0.781 11 LNU68 14034.1 0.83 0.225 8 LNU122 25332.2 12.63 0.009 8 LNU287 24674.3 0.87 0.766 7 LNU71 25852.5 0.93 0.211 21 LNU122 25332.5 12.63 0.078 8 LNU37 14064.7 1.02 0.001 25 LNU71 25853.1 0.89 0.012 16 LNU122 25333.1 12.19 0.066 4 LNU37 14064.6 0.94 0.579 14 LNU71 25851.4 0.88 0.005 15 LNU122 25333.2 12.19 0.313 4 LNU5 14043.9 1.04 0.159 27 LNU72 24963.7 0.90 0.324 18 LNU122 25332.1 12.13 0.123 4 LNU5 14043.7 0.85 0.539 4 LNU72 24962.3 0.80 0.774 5 LNU125 25944.3 12.25 0.633 5 LNU65 24702.3 0.91 0.471 11 LNU74 25443.3 0.92 0.166 20 LNU25 14082.8 12.19 0.646 4 LNU65 24703.6 0.88 0.539 7 LNU82 24823.1 0.81 0.171 6 LNU267 25804.3 12.25 0.525 5 LNU68 14034.13 1.07 0.318 30 LNU84 25621.2 0.78 0.779 3 LNU45 25053.4 12.13 0.281 4 LNU71 25853.1 1.03 0.001 26 LNU84 25621.4 0.78 0.734 2 LNU67 25821.5 12.31 0.238 5 LNU71 25852.5 0.99 0.014 22 LNU87 24712.1 0.84 0.600 10 CONT. — 10.39 — 0 LNU71 25851.4 0.95 0.352 16 LNU98 25763.2 0.81 0.213 6 LNU100 14472.1 11.19 0.381 8 LNU72 24963.7 0.95 0.423 16 CONT. — 0.84 — 0 LNU100 14473.1 11.19 0.065 8 LNU74 25443.3 0.95 0.507 16 LNU117 25933.3 1.05 0.197 25 LNU100 14473.3 11.13 0.000 7 LNU82 24823.1 0.89 0.342 9 LNU117 25931.4 1.00 0.145 20 LNU104 25032.1 11.81 0.165 14 LNU84 25621.2 0.93 0.311 13 LNU117 25931.1 0.92 0.407 10 LNU104 25032.2 11.69 0.000 13 LNU84 25621.4 0.91 0.089 11 LNU117 25931.2 0.87 0.716 3 LNU104 25033.3 11.56 0.030 11 CONT. — 1.01 — 0 LNU117 25932.4 0.86 0.577 3 LNU104 25033.8 10.94 0.416 5 LNU117 25931.4 1.38 0.070 37 LNU122 25332.5 0.95 0.368 13 LNU104 25033.1 10.88 0.576 5 LNU117 25933.3 1.26 0.013 25 LNU122 25332.1 0.95 0.014 13 LNU106 14483.5 11.00 0.028 6 LNU117 25932.4 1.10 0.235 8 LNU122 25333.1 0.92 0.412 9 LNU106 14483.2 10.94 0.416 5 LNU117 25931.1 1.09 0.286 8 LNU122 25332.2 0.89 0.313 6 LNU106 14484.3 10.78 0.451 4 LNU117 25931.2 1.04 0.773 2 LNU122 25333.2 0.88 0.182 5 LNU114 25041.2 11.31 0.049 9 LNU122 25333.2 1.24 0.029 23 LNU125 25941.4 0.98 0.080 17 LNU114 25041.1 11.13 0.149 7 LNU122 25332.2 1.20 0.063 19 LNU125 25944.3 0.97 0.096 15 LNU114 25042.1 10.69 0.063 3 LNU122 25333.1 1.20 0.045 19 LNU125 25941.2 0.88 0.608 5 LNU117 25931.4 10.94 0.297 5 LNU122 25332.5 1.15 0.331 14 LNU138 14074.6 0.98 0.005 17 LNU155 14525.1 11.06 0.001 6 LNU122 25332.1 1.14 0.392 13 LNU138 14074.5 0.97 0.064 15 LNU218 24781.2 10.94 0.568 5 LNU125 25941.4 1.28 0.010 26 LNU180 24723.1 0.89 0.138 7 LNU218 24781.6 10.94 0.128 5 LNU125 25941.2 1.06 0.598 5 LNU180 24724.1 0.89 0.519 6 LNU218 24781.1 10.88 0.255 5 LNU138 14074.5 1.24 0.018 23 LNU180 24722.2 0.87 0.400 4 LNU254 25782.4 11.56 0.000 11 LNU138 14074.6 1.23 0.080 22 LNU180 24721.2 0.87 0.704 3 LNU4 25134.1 11.63 0.000 12 LNU180 24722.2 1.07 0.420 6 LNU220 25405.6 0.93 0.053 11 LNU4 25133.3 11.06 0.239 6 LNU220 25405.1 1.11 0.197 10 LNU230 25413.2 0.96 0.537 14 LNU4 25131.1 11.00 0.427 6 LNU220 25405.3 1.08 0.473 7 LNU230 25412.2 0.91 0.548 8 LNU4 25134.3 10.88 0.255 5 LNU220 25405.6 1.07 0.722 6 LNU230 25413.1 0.90 0.566 8 LNU40 24792.1 11.56 0.030 11 LNU230 25413.1 1.26 0.345 25 LNU230 25412.1 0.87 0.343 4 LNU40 24794.3 10.88 0.255 5 LNU230 25412.2 1.20 0.501 19 LNU25 14082.8 0.97 0.007 16 LNU40 24794.4 10.81 0.381 4 LNU230 25413.2 1.16 0.643 15 LNU25 14082.9 0.93 0.069 11 LNU46 14462.5 11.50 0.082 11 LNU25 14083.7 1.14 0.520 12 LNU25 14083.1 0.93 0.025 11 LNU46 14462.1 11.06 0.089 6 LNU25 14082.9 1.10 0.226 9 LNU254 25782.4 0.92 0.529 9 LNU48 24802.2 11.50 0.004 11 LNU25 14083.1 1.10 0.227 9 LNU254 25781.3 0.88 0.169 5 LNU48 24804.4 10.81 0.194 4 LNU25 14082.8 1.07 0.473 6 LNU254 25782.5 0.87 0.508 4 LNU48 24802.1 10.75 0.502 3 LNU254 25781.3 1.09 0.263 8 LNU263 25791.3 1.03 0.308 23 LNU48 24801.4 10.70 0.320 3 LNU254 25782.5 1.07 0.363 6 LNU263 25794.8 1.01 0.074 20 LNU63 24814.2 11.13 0.149 7 LNU254 25782.4 1.06 0.671 5 LNU267 25804.3 0.89 0.244 7 LNU63 24814.7 10.94 0.297 5 LNU263 25791.3 1.25 0.376 23 LNU271 25913.3 0.93 0.373 11 LNU7 25081.1 11.56 0.271 11 LNU263 25794.8 1.22 0.078 21 LNU278 25812.3 0.94 0.232 12 LNU8 25063.1 11.38 0.098 10 LNU267 25804.3 1.03 0.799 2 LNU278 25814.1 0.88 0.251 4 LNU8 25062.1 11.23 0.337 8 LNU271 25913.3 1.10 0.642 9 LNU36 25562.3 0.90 0.540 7 LNU8 25061.2 11.06 0.001 6 LNU271 25912.1 1.05 0.719 4 LNU36 25562.9 0.87 0.797 4 LNU8 25062.2 10.81 0.586 4 LNU278 25814.3 1.16 0.190 15 LNU36 25562.7 0.87 0.704 3 LNU94 24833.3 11.50 0.252 11 LNU278 25812.3 1.07 0.388 6 LNU43 14421.1 0.99 0.255 18 LNU94 24834.4 11.13 0.149 7 LNU36 25562.3 1.15 0.107 14 LNU43 14422.8 0.96 0.014 15 LNU94 24831.4 10.88 0.401 5 LNU43 14423.6 1.21 0.313 20 LNU43 14423.6 0.93 0.587 11 LNU94 24833.1 10.81 0.381 4 LNU43 14422.8 1.13 0.122 12 LNU43 14423.7 0.88 0.607 5 LNU96 25071.2 11.44 0.141 10 LNU43 14421.1 1.11 0.465 10 LNU45 25053.4 0.93 0.154 11 LNU96 25071.3 11.19 0.299 8 LNU43 14422.9 1.08 0.337 7 LNU45 25052.9 0.86 0.458 3 LNU96 25073.4 11.13 0.149 7 LNU45 25053.4 1.22 0.027 21 LNU67 25824.5 1.02 0.168 21 CONT. — 10.00 — 0 LNU67 25824.5 1.29 0.024 28 LNU67 25821.5 0.97 0.324 16 LNU122 25332.5 10.88 0.388 9 LNU67 25821.5 1.27 0.200 26 LNU67 25823.5 0.91 0.481 9 LNU122 25332.2 10.63 0.323 6 LNU67 25823.5 1.06 0.563 5 LNU67 25821.4 0.90 0.545 7 LNU125 25944.1 10.69 0.089 7 CONT. — 0.78 — 0 CONTROL — 0.82 — 0 LNU125 25941.4 10.56 0.292 6 LNU100 14472.1 0.96 0.137 23 LNU100 14473.1 0.98 0.000 18 LNU125 25943.2 10.31 0.297 3 LNU100 14473.3 0.92 0.300 19 LNU100 14472.1 0.94 0.041 15 LNU178 14611.5 10.31 0.603 3 LNU100 14473.1 0.92 0.061 18 LNU100 14473.3 0.86 0.298 5 LNU236 25425.3 10.50 0.003 5 LNU104 25032.2 1.05 0.002 35 LNU104 25032.2 1.02 0.179 24 LNU236 25422.4 10.31 0.053 3 LNU104 25033.3 0.97 0.085 24 LNU104 25033.3 1.00 0.144 21 LNU236 25424.2 10.25 0.488 3 LNU104 25032.1 0.84 0.203 8 LNU104 25032.1 0.87 0.339 6 LNU25 14082.8 10.44 0.493 4 LNU106 14483.2 0.94 0.396 21 LNU106 14481.1 0.92 0.716 11 LNU271 25912.1 10.19 0.492 2 LNU106 14483.5 0.90 0.119 16 LNU106 14483.5 0.90 0.549 9 LNU278 25814.3 10.50 0.394 5 LNU106 14481.1 0.90 0.504 15 LNU106 14483.2 0.85 0.510 3 LNU278 25814.1 10.25 0.238 3 LNU106 14484.3 0.83 0.332 6 LNU106 14484.3 0.85 0.708 3 LNU45 25053.4 10.50 0.394 5 LNU114 25041.2 1.01 0.294 29 LNU114 25041.1 0.95 0.413 15 LNU45 25052.11 10.38 0.108 4 LNU114 25044.4 0.86 0.562 10 LNU114 25041.2 0.89 0.303 8 LNU45 25052.12 10.25 0.795 3 LNU114 25041.1 0.82 0.781 5 LNU117 25931.4 0.97 0.303 17 LNU67 25823.5 10.63 0.028 6 LNU114 25042.1 0.81 0.797 4 LNU117 25932.4 0.92 0.034 11 CONT. — 11.19 — 0 LNU117 25931.4 0.96 0.082 23 LNU117 25931.2 0.85 0.452 3 LNU168 24753.5 11.75 0.638 5 LNU117 25931.1 0.86 0.211 11 LNU218 24781.6 0.94 0.521 15 LNU173 25451.1 11.69 0.034 4 LNU155 14523.5 0.83 0.659 7 LNU218 24781.4 0.92 0.006 12 LNU173 25451.2 11.50 0.417 3 LNU218 24781.4 0.95 0.00 22 LNU218 24781.1 0.85 0.709 4 LNU178 14611.1 12.00 0.002 7 LNU218 24781.6 0.85 0.545 9 LNU254 25782.4 0.87 0.129 6 LNU178 14611.5 11.94 0.185 7 LNU218 24781.1 0.81 0.390 5 LNU4 25133.3 0.94 0.351 15 LNU184 25393.1 11.56 0.425 3 LNU254 25782.4 0.86 0.005 11 LNU4 25134.3 0.85 0.490 4 LNU230 25412.2 11.75 0.194 5 LNU4 25133.3 0.88 0.002 13 LNU40 24792.1 1.00 0.002 22 LNU230 25413.1 11.63 0.282 4 LNU4 25134.3 0.84 0.020 8 LNU40 24794.4 0.93 0.513 13 LNU236 25425.4 11.63 0.666 4 LNU4 25134.2 0.82 0.704 5 LNU40 24794.3 0.84 0.528 2 LNU236 25423.3 11.44 0.263 2 LNU40 24792.1 1.04 0.308 34 LNU46 14462.1 0.92 0.101 12 LNU236 25424.2 11.44 0.263 2 LNU40 24794.4 0.86 0.426 11 LNU46 14462.5 0.92 0.485 12 LNU24 24971.2 11.81 0.239 6 LNU40 24792.2 0.82 0.640 5 LNU46 14463.2 0.89 0.140 8 LNU263 25794.8 11.44 0.578 2 LNU40 24794.3 0.81 0.695 4 LNU48 24801.4 0.96 0.263 17 LNU276 25431.1 12.13 0.282 8 LNU46 14462.5 1.05 0.329 35 LNU48 24802.1 0.90 0.388 10 LNU276 25433.3 12.00 0.002 7 LNU46 14462.1 0.97 0.001 24 LNU48 24804.4 0.86 0.455 4 LNU279 25481.3 11.44 0.420 2 LNU48 24801.4 0.95 0.000 22 LNU48 24802.2 0.85 0.800 3 LNU53 25674.6 11.63 0.103 4 LNU48 24802.1 0.92 0.437 18 LNU63 24814.6 0.93 0.402 13 LNU73 25751.9 11.63 0.103 4 LNU48 24803.2 0.81 0.631 3 LNU63 24814.7 0.86 0.545 4 LNU9 25001.2 11.50 0.417 3 LNU63 24814.2 0.93 0.009 20 LNU63 24814.2 0.86 0.533 4 LNU9 25001.7 11.50 0.417 3 LNU63 24814.6 0.88 0.064 13 LNU7 25081.1 0.92 0.467 12 LNU9 25001.3 11.44 0.578 2 LNU63 24812.2 0.80 0.703 3 LNU8 25063.1 0.91 0.182 11 CONT. — 8.5 — 0 LNU63 24812.3 0.80 0.542 2 LNU8 25062.1 0.89 0.508 9 LNU131 14005.2 9.63 0.000 13 LNU7 25081.1 0.91 0.017 17 LNU8 25062.2 0.87 0.493 6 LNU131 14002.15 9.25 0.371 9 LNU7 25083.1 0.82 0.766 5 LNU8 25061.2 0.85 0.329 4 LNU131 14005.5 9.25 0.000 9 LNU7 25083.3 0.81 0.337 4 LNU94 24831.4 0.94 0.025 15 LNU135 26204.4 9.25 0.444 9 LNU8 25063.1 0.96 0.184 23 LNU94 24833.1 0.90 0.463 9 LNU135 26204.2 9.13 0.033 7 LNU8 25062.1 0.89 0.480 14 LNU94 24833.3 0.86 0.278 5 LNU135 26203.1 9.06 0.505 6 LNU8 25061.2 0.84 0.400 8 LNU96 25071.3 0.87 0.751 6 LNU135 26203.3 9.06 0.140 6 LNU8 25062.2 0.82 0.204 6 LNU96 25071.2 0.87 0.169 6 LNU135 26203.4 9.06 0.622 6 LNU94 24833.1 0.95 0.000 22 CONT. — 0.83 — 0 LNU173 25451.2 9.56 0.417 12 LNU94 24833.3 0.94 0.127 21 LNU10 25123.5 0.90 0.591 8 LNU173 25451.5 9.13 0.202 7 LNU94 24831.4 0.94 0.036 21 LNU122 25332.5 0.93 0.021 11 LNU181 25774.1 9.44 0.000 11 LNU94 24834.4 0.90 0.624 15 LNU122 25332.2 0.88 0.460 6 LNU181 25771.6 9.31 0.076 9 LNU96 25071.2 0.86 0.223 10 LNU122 25332.1 0.85 0.615 3 LNU181 25771.8 8.88 0.118 4 LNU96 25073.4 0.86 0.195 10 LNU125 25941.4 0.92 0.309 11 LNU181 25771.5 8.81 0.508 3 LNU96 25071.3 0.82 0.753 5 LNU178 14611.1 0.86 0.609 3 LNU181 25771.2 8.69 0.762 2 CONT. — 0.80 — 0 LNU234 25014.4 0.93 0.115 12 LNU184 25393.2 9.56 0.000 12 LNU10 25123.5 0.95 0.358 19 LNU236 25425.3 0.92 0.298 11 LNU184 25394.1 9.13 0.202 7 LNU122 25332.5 1.04 0.000 30 LNU236 25425.4 0.89 0.516 8 LNU184 25393.1 9.06 0.140 6 LNU122 25332.2 0.93 0.177 17 LNU236 25423.3 0.86 0.230 3 LNU184 25394.3 9.06 0.420 6 LNU122 25332.1 0.88 0.010 10 LNU25 14082.8 0.93 0.045 12 LNU184 25393.3 9.04 0.334 6 LNU125 25941.4 0.91 0.015 14 LNU25 14083.7 0.91 0.407 9 LNU184 25395.1 9.00 0.407 6 LNU125 25943.2 0.87 0.021 10 LNU267 25803.1 0.87 0.095 5 LNU224 25872.3 9.75 0.080 14 LNU178 14611.5 0.94 0.197 18 LNU271 25913.3 0.91 0.307 10 LNU224 25874.1 9.69 0.131 14 LNU178 14611.1 0.89 0.325 12 LNU271 25911.4 0.85 0.380 3 LNU224 25874.4 9.56 0.150 12 LNU178 14612.1 0.85 0.692 6 LNU278 25814.1 0.93 0.001 12 LNU224 25872.2 9.00 0.678 6 LNU220 25405.1 0.82 0.402 3 LNU278 25814.3 0.88 0.054 6 LNU224 25871.3 8.88 0.118 4 LNU234 25014.5 0.91 0.519 14 LNU278 25812.2 0.86 0.687 4 LNU246 25744.2 9.69 0.131 14 LNU234 25014.4 0.89 0.324 12 LNU43 14423.7 0.86 0.635 3 LNU246 25744.3 9.69 0.039 14 LNU234 25014.6 0.88 0.716 11 LNU45 25052.12 0.95 0.351 15 LNU246 25744.4 9.13 0.505 7 LNU236 25423.3 0.87 0.160 10 LNU45 25053.4 0.92 0.098 10 LNU246 25743.2 8.81 0.508 3 LNU236 25424.2 0.85 0.481 7 LNU45 25052.11 0.86 0.741 3 LNU246 25743.1 8.77 0.634 3 LNU236 25425.3 0.84 0.790 5 LNU67 25823.5 0.96 0.000 15 LNU250 25591.1 9.44 0.174 11 LNU236 25425.4 0.83 0.385 5 LNU9 25001.1 0.88 0.507 7 LNU250 25592.2 8.94 0.388 5 LNU25 14083.7 0.93 0.119 17 LNU9 25001.7 0.85 0.430 2 LNU250 25591.3 8.88 0.118 4 LNU25 14082.8 0.85 0.075 7 CONT. — 0.91 — 0 LNU260 26404.1 9.44 0.059 11 LNU267 25803.1 0.83 0.236 4 LNU10 25123.6 0.99 0.534 9 LNU260 26403.1 8.88 0.007 4 LNU271 25911.4 0.92 0.001 16 LNU157 24982.7 0.96 0.550 5 LNU260 26404.7 8.81 0.317 3 LNU271 25913.3 0.82 0.358 3 LNU168 24753.5 0.98 0.046 8 LNU762 25433.6 9.56 0.304 12 LNU271 25912.1 0.81 0.607 2 LNU173 25451.1 1.04 0.071 14 LNU276 25433.3 9.19 0.247 8 LNU278 25814.3 0.98 0.000 23 LNU178 14611.4 1.02 0.358 12 LNU276 25433.5 9.00 0.407 6 LNU278 25814.1 0.97 0.000 22 LNU178 14611.5 1.00 0.524 9 LNU276 25431.1 8.75 0.511 3 LNU278 25812.3 0.89 0.147 12 LNU178 14611.1 0.98 0.049 7 LNU279 25484.3 9.38 0.131 10 LNU278 25813.2 0.88 0.659 10 LNU184 25395.1 1.04 0.002 14 LNU279 25481.3 9.19 0.000 8 LNU278 25812.2 0.85 0.696 6 LNU184 25393.1 1.03 0.381 13 LNU279 25481.2 8.88 0.118 4 LNU43 14423.6 0.89 0.316 12 LNU184 25394.3 1.03 0.335 13 LNU279 25481.4 8.69 0.680 2 LNU43 14423.7 0.85 0.376 7 LNU184 25393.2 1.01 0.354 11 LNU3 26124.3 9.60 0.002 6 LNU45 25052.12 1.00 0.263 26 LNU23 25413.2 1.06 0.291 17 LNU3 26122.2 8.75 0.643 3 LNU45 25053.4 0.97 0.179 21 LNU230 25415.1 1.05 0.005 16 LNU33 25552.2 9.25 0.020 9 LNU45 25052.9 0.88 0.137 10 LNU230 25412.2 1.02 0.344 12 LNU33 25553.3 9.19 0.355 8 LNU45 25052.11 0.86 0.590 8 LNU230 25413.1 1.00 0.012 10 LNU53 25674.5 8.69 0.214 2 LNU67 25823.5 1.10 0.003 38 LNU230 25412.1 0.93 0.714 2 LNU53 25674.6 8.69 0.762 2 LNU67 25824.3 0.83 0.751 5 LNU236 25424.2 1.06 0.447 16 CONT. — 10.18 — 0 LNU67 25824.5 0.82 0.693 3 LNU236 25425.4 1.03 0.545 13 LNU119 26142.8 10.44 0.112 3 LNU67 25821.5 0.82 0.558 3 LNU236 25423.3 1.01 0.324 11 LNU130 24913.6 10.75 0.206 6 LNU9 25001.7 0.89 0.264 12 LNU24 24971.2 1.08 0.157 19 LNU130 24912.7 10.56 0.222 4 LNU9 25003.1 0.85 0.350 6 LNU24 24974.2 0.99 0.440 9 LNU130 24911.7 10.38 0.567 2 LNU9 25001.3 0.82 0.418 3 LNU24 24971.3 0.97 0.303 6 LNU136 14515.1 11.06 0.051 9 CONT. — 1.00 — 0 LNU24 24971.4 0.93 0.796 2 LNU142 27541.1 10.63 0.009 4 LNU10 25123.6 1.30 0.206 30 LNU263 25794.8 1.04 0.342 14 LNU142 27545.1 10.50 0.632 3 LNU10 25123.5 1.16 0.000 16 LNU276 25433.3 1.00 0.036 9 LNU142 27546.2 10.44 0.363 3 LNU157 24982.8 1.11 0.005 11 LNU276 25431.1 0.93 0.716 2 LNU149 26175.1 10.88 0.458 7 LNU157 24982.4 1.09 0.165 9 LNU279 25481.3 0.98 0.043 8 LNU149 26175.7 10.69 0.143 5 LNU168 24753.5 1.05 0.467 5 LNU279 25481.4 0.96 0.480 6 LNU15 14123.11 10.44 0.363 3 LNU173 25451.1 1.08 0.026 8 LNU36 25562.3 1.00 0.294 10 LNU185 26474.2 11.00 0.242 8 LNU173 25451.2 1.05 0.537 5 LNU53 25674.1 1.08 0.187 18 LNU185 26475.1 10.38 0.567 2 LNU178 14611.5 1.20 0.032 20 LNU53 25674.2 1.06 0.073 16 LNU212 25834.1 10.75 0.002 6 LNU178 14611.4 1.19 0.217 19 LNU53 25674.6 0.96 0.197 5 LNU212 25834.5 10.69 0.007 5 LNU178 14611.1 1.18 0.069 18 LNU56 24694.1 1.01 0.043 11 LNU212 25834.4 10.37 0.772 2 LNU184 25393.2 1.28 0.000 28 LNU56 24694.2 0.98 0.420 8 LNU212 25832.1 10.35 0.224 2 LNU184 25393.1 1.25 0.468 25 LNU56 24693.1 0.98 0.048 7 LNU216 25982.2 10.69 0.439 5 LNU184 25394.3 1.21 0.440 21 LNU56 24693.2 0.96 0.202 6 LNU216 25984.6 10.69 0.143 5 LNU184 25395.1 1.19 0.089 19 LNU73 25751.1 1.06 0.531 16 LNU216 25985.4 10.50 0.539 3 LNU184 25393.3 1.02 0.563 2 LNU73 25755.1 1.04 0.223 14 LNU216 25982.1 10.44 0.363 3 LNU230 25415.1 1.34 0.109 34 LNU73 25754.2 1.00 0.624 9 LNU228 26224.7 10.81 0.002 6 LNU230 25412.1 1.18 0.043 18 LNU73 25751.9 0.99 0.205 8 LNU228 26222.4 10.56 0.222 4 LNU230 25413.2 1.17 0.119 17 LNU73 25751.8 0.97 0.778 6 LNU228 26224.6 10.44 0.549 3 LNU230 25413.1 1.15 0.021 15 LNU9 25001.7 1.07 0.049 17 LNU274 26265.1 10.44 0.112 3 LNU230 25412.2 1.13 0.020 13 LNU9 25001.2 1.03 0.562 13 LNU274 26262.2 10.38 0.689 2 LNU236 25425.4 1.25 0.002 25 LNU9 25001.1 1.00 0.008 10 LNU277 25845.1 10.56 0.413 4 LNU236 25424.2 1.22 0.064 23 LNU9 25001.3 0.97 0.625 6 LNU280 26164.2 10.88 0.001 7 LNU236 25422.4 1.17 0.000 17 LNU9 25003.1 0.96 0.591 5 LNU280 26164.4 10.69 0.591 5 LNU236 25423.3 1.17 0.372 17 CONT. — 0.60 — 0 LNU280 26162.1 10.56 0.413 4 LNU24 24974.2 1.19 0.247 20 LNU131 14005.2 0.87 0.000 45 LNU55 26015.3 10.56 0.028 4 LNU24 24971.3 1.16 0.500 16 LNU131 14005.5 0.78 0.003 29 LNU81 26034.2 10.50 0.632 3 LNU24 24971.2 1.10 0.172 10 LNU135 26203.1 0.78 0.594 29 LNU81 26034.3 10.50 0.632 3 LNU24 24972.1 1.07 0.056 7 LNU135 26204.2 0.70 0.288 16 CONT. — 10.58 — 0 LNU24 24971.4 1.03 0.781 3 LNU135 26203.4 0.68 0.746 13 LNU119 26142.8 10.81 0.330 2 LNU263 25794.8 1.28 0.169 28 LNU135 26203.3 0.62 0.559 3 LNU130 24913.5 11.44 0.040 8 LNU263 25791.3 1.11 0.713 11 LNU161 14552.9 0.70 0.356 16 LNU136 14511.10 11.19 0.032 6 LNU276 25433.3 1.28 0.035 29 LNU173 25451.2 0.72 0.605 19 LNU136 14515.1 10.88 0.444 3 LNU276 25431.1 1.03 0.504 3 LNU181 25774.1 0.76 0.002 26 LNU142 27545.1 11.38 0.106 7 LNU279 25481.3 1.24 0.341 24 LNU181 25771.8 0.76 0.085 26 LNU142 27541.1 11.19 0.100 6 LNU279 25481.5 1.20 0.322 20 LNU181 25771.6 0.69 0.368 14 LNU212 25834.5 11.44 0.262 8 LNU279 25481.4 1.18 0.055 18 LNU181 25771.5 0.66 0.207 9 LNU212 25833.2 11.19 0.249 6 LNU279 25484.3 1.05 0.606 5 LNU184 25393.1 0.79 0.182 31 LNU216 25984.6 11.06 0.165 5 LNU36 25562.3 1.06 0.391 6 LNU184 25393.3 0.79 0.416 30 LNU216 25982.2 10.88 0.444 3 LNU36 25562.7 1.05 0.251 5 LNU184 25394.1 0.74 0.234 23 LNU216 25984.1 10.81 0.459 2 LNU53 25674.1 1.30 0.163 30 LNU184 25394.3 0.74 0.498 23 LNU228 26222.1 11.00 0.302 4 LNU53 25674.2 1.07 0.456 7 LNU184 25393.2 0.71 0.003 18 LNU228 26224.7 10.94 0.276 3 LNU53 25674.6 1.07 0.042 7 LNU184 25395.1 0.65 0.404 8 LNU274 26264.2 11.06 0.165 5 LNU56 24693.1 1.14 0.252 14 LNU224 25872.3 0.93 0.003 54 LNU277 25842.3 10.88 0.275 3 LNU56 24694.1 1.13 0.018 13 LNU224 25874.4 0.82 0.142 36 LNU280 26164.4 11.00 0.099 4 LNU56 24693.2 1.08 0.395 8 LNU224 25874.1 0.77 0.387 28 LNU55 26013.9 10.81 0.756 2 LNU73 25755.1 1.22 0.115 22 LNU224 25872.2 0.77 0.403 27 LNU81 26034.2 11.00 0.552 4 LNU73 25751.1 1.19 0.593 19 LNU224 25871.3 0.63 0.558 4 LNU81 26031.10. 10.88 0.665 3 LNU73 25754.2 1.16 0.492 16 LNU246 25744.2 0.79 0.201 32 LNU81 26034.3 10.88 0.578 3 LNU73 25751.8 1.14 0.457 14 LNU246 25744.3 0.78 0.375 29 LNU73 25751.9 1.09 0.180 9 LNU246 25744.4 0.77 0.608 27 LNU9 25001.1 1.30 0.010 30 LNU250 25591.1 0.90 0.167 49 LNU9 25001.7 1.19 0.260 19 LNU250 25592.2 0.81 0.002 34 LNU9 25001.3 1.16 0.365 16 LNU260 26404.1 0.66 0.499 10 LNU9 25001.2 1.14 0.394 14 LNU260 26403.1 0.64 0.234 6 CONT. — 0.86 — 0 LNU276 25433.6 0.83 0.201 37 LNU131 14005.2 1.26 0.000 46 LNU276 25433.5 0.74 0.245 22 LNU131 14005.5 1.13 0.000 31 LNU279 25481.3 0.86 0.338 43 LNU135 26203.4 0.96 0.768 11 LNU279 25484.3 0.71 0.486 17 LNU135 26204.2 0.93 0.333 8 LNU279 25481.5 0.69 0.577 14 LNU173 25451.2 0.99 0.530 15 LNU3 26123.5 0.71 0.515 18 LNU181 25771.8 1.10 0.417 27 LNU3 26124.1 0.70 0.779 15 LNU181 25771.5 1.00 0.513 16 LNU3 26124.3 0.67 0.035 12 LNU181 25771.6 1.00 0.014 16 LNU3 26123.6 0.66 0.533 9 LNU181 25774.1 0.94 0.123 9 LNU3 26122.2 0.65 0.194 8 LNU184 25393.2 1.11 0.000 29 LNU33 25552.2 0.67 0.463 11 LNU184 25394.1 1.07 0.293 24 LNU33 25553.3 0.66 0.224 10 LNU184 25393.1 0.99 0.197 15 LNU53 25674.5 0.72 0.129 19 LNU184 25393.3 0.99 0.655 15 LNU53 25674.1 0.68 0.641 13 LNU184 25394.3 0.95 0.736 11 LNU53 25674.6 0.63 0.661 4 LNU224 25872.3 1.26 0.036 46 LNU56 24694.2 0.70 0.010 16 LNU224 25874.4 1.11 0.110 29 CONT. — 0.88 — 0 LNU224 25874.1 1.11 0.416 29 LNU130 24912.7 1.07 0.223 21 LNU224 25872.2 1.08 0.309 25 LNU130 24911.7 1.00 0.492 13 LNU246 25744.4 1.13 0.553 31 LNU130 24913.6 0.95 0.430 8 LNU246 25744.3 1.13 0.587 31 LNU130 24914.5 0.90 0.785 3 LNU246 25744.2 1.10 0.259 28 LNU136 14515.1 1.01 0.272 14 LNU246 25743.1 1.06 0.214 23 LNU142 27541.1 0.96 0.031 9 LNU246 25743.2 0.95 0.095 11 LNU149 26175.1 0.92 0.662 5 LNU250 25591.1 1.23 0.129 43 LNU15 14123.11 1.01 0.138 15 LNU250 25592.2 1.01 0.010 17 LNU15 14122.9 0.95 0.466 8 LNU260 26404.1 0.91 0.655 5 LNU15 14122.8 0.94 0.149 7 LNU276 25433.6 1.12 0.280 30 LNU15 14123.13 0.93 0.183 6 LNU276 25433.5 0.96 0.621 12 LNU185 26475.1 1.03 0.395 18 LNU279 25481.3 1.19 0.435 38 LNU185 26472.1 0.99 0.436 13 LNU279 25484.3 1.16 0.212 34 LNU185 26474.2 0.98 0.028 11 LNU279 25481.5 0.97 0.605 12 LNU212 25834.5 0.98 0.025 12 LNU279 25481.2 0.96 0.279 12 LNU212 25834.1 0.96 0.391 10 LNU33 25553.3 0.96 0.576 11 LNU216 25982.1 1.01 0.001 15 LNU53 25674.5 0.92 0.285 7 LNU216 25985.4 0.97 0.557 10 LNU56 24694.2 0.93 0.292 8 LNU216 25984.1 0.91 0.292 4 CONT. — 1.03 — 0 LNU216 25984.6 0.90 0.693 2 LNU119 26142.8 1.07 0.559 4 LNU228 26222.4 1.10 0.057 25 LNU130 24912.7 1.26 0.102 23 LNU228 26222.1 0.95 0.291 8 LNU130 24913.5 1.14 0.374 11 LNU228 26224.6 0.93 0.423 6 LNU130 24911.7 1.11 0.732 7 LNU229 26112.3 0.96 0.264 9 LNU130 24913.6 1.07 0.672 4 LNU229 26111.7 0.95 0.079 8 LNU136 14515.1 1.18 0.067 15 LNU241 26232.4 0.99 0.432 12 LNU142 27541.1 1.13 0.533 10 LNU241 26233.2 0.92 0.441 5 LNU142 27545.1 1.10 0.737 6 LNU253 26243.3 0.90 0.536 2 LNU15 14123.13 1.15 0.362 11 LNU274 26262.2 0.95 0.487 8 LNU15 14123.11 1.11 0.073 8 LNU280 26162.1 1.04 0.456 18 LNU185 26475.1 1.18 0.387 15 LNU280 26162.7 0.96 0.248 9 LNU185 26474.2 1.07 0.388 4 LNU280 26164.4 0.95 0.713 7 LNU212 25834.5 1.20 0.002 16 LNU55 26015.1 1.05 0.364 19 LNU212 25834.1 1.11 0.719 8 LNU55 26015.3 0.92 0.303 5 LNU216 25985.4 1.17 0.706 13 LNU81 26034.3 1.01 0.003 14 LNU216 25982.1 1.10 0.527 6 CONT. — 0.94 — 0 LNU228 26224.7 1.09 0.568 6 LNU119 26142.8 1.05 0.360 12 LNU228 26222.4 1.09 0.344 6 LNU119 26144.2 1.03 0.028 9 LNU241 26233.2 1.11 0.160 8 LNU119 26141.1 1.03 0.219 9 LNU241 26232. 1.06 0.592 3 LNU130 24913.5 1.06 0.379 12 LNU274 26262.2 1.08 0.753 5 LNU130 24914.5 1.03 0.141 10 LNU274 26265.1 1.06 0.397 3 LNU136 14515.1 1.06 0.310 13 LNU277 25845.1 1.18 0.363 15 LNU142 27541.2 1.06 0.366 13 LNU280 26162.1 1.23 0.563 20 LNU142 27541.1 1.03 0.521 10 LNU280 26162.7 1.15 0.086 12 LNU142 27545.1 1.03 0.100 9 LNU55 26015.1 1.12 0.158 9 LNU149 26174.7 1.05 0.622 12 LNU55 26015.3 1.05 0.540 2 LNU15 14122.8 1.20 0.478 28 LNU81 26034.3 1.26 0.001 22 LNU15 14123.11 1.12 0.500 19 CONT. — 1.10 — 0 LNU15 14123.13 1.05 0.263 12 LNU119 26142.8 1.27 0.139 16 LNU15 14122.9 0.99 0.563 5 LNU119 26141.1 1.27 0.565 15 LNU185 26472.1 1.04 0.507 11 LNU130 24914.5 1.32 0.004 20 LNU185 26474.2 0.98 0.645 4 LNU136 14515.1 1.21 0.274 10 LNU185 26474.1 0.96 0.547 2 LNU142 27541.1 1.21 0.638 10 LNU212 25834.5 1.05 0.388 11 LNU142 27541.2 1.17 0.098 6 LNU212 25834.1 1.04 0.612 11 LNU15 14123.11 1.42 0.327 29 LNU212 25833.2 1.04 0.551 11 LNU15 14122.8 1.36 0.570 24 LNU212 25834.4 1.00 0.545 6 LNU15 14123.13 1.25 0.308 13 LNU216 25984.6 1.09 0.113 16 LNU185 26474.1 1.20 0.433 9 LNU216 25984.1 1.05 0.100 12 LNU212 25834.5 1.24 0.411 13 LNU216 25982.2 0.99 0.087 6 LNU212 25834.4 1.18 0.605 7 LNU216 25982.1 0.98 0.148 5 LNU212 25834.1 1.17 0.479 6 LNU228 26224.7 1.17 0.050 25 LNU212 25833.2 1.15 0.765 4 LNU228 26224.6 1.04 0.620 11 LNU216 25984.1 1.19 0.587 8 LNU228 26222.1 1.04 0.028 11 LNU216 25982.2 1.16 0.031 6 LNU228 26225.2 0.99 0.120 5 LNU216 25984.6 1.14 0.675 4 LNU229 26111.5 1.00 0.301 6 LNU228 26224.7 1.33 0.012 21 LNU241 26232.4 1.06 0.094 13 LNU228 26222.1 1.30 0.015 18 LNU253 26243.3 1.03 0.292 9 LNU228 26225.2 1.14 0.627 3 LNU274 26262.2 1.00 0.069 6 LNU229 26111.5 1.27 0.000 15 LNU277 25842.3 1.09 0.283 16 LNU229 26112.4 1.13 0.720 3 LNU277 25844.3 0.98 0.547 5 LNU241 26232.4 1.30 0.340 18 LNU280 26164.3 1.08 0.014 15 LNU253 26242.1 1.17 0.621 6 LNU280 26162.7 1.06 0.452 13 LNU274 26262.2 1.15 0.489 5 LNU280 26164.4 1.04 0.114 11 LNU277 25842.3 1.24 0.486 13 LNU280 26162.1 1.04 0.496 11 LNU280 26164.4 1.25 0.101 13 LNU55 26013.4 0.96 0.409 3 LNU280 26162.1 1.18 0.024 7 LNU81 26031.10 1.14 0.307 21 LNU81 26031.10 1.38 0.204 25 LNU81 26034.3 1.11 0.438 18 LNU81 26031.9 1.17 0.607 6 LNU81 26034.2 1.05 0.021 12 LNU81 26031.9 0.97 0.711 3 Table 84. “CONT.” Control; “Ave.” Average; “% Incr.” = % increment.

Although the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the spirit and broad scope of the appended claims.

It is the intent of the Applicant(s) that all publications, patents and patent applications referred to in this specification are to be incorporated in their entirety by reference into the specification, as if each individual publication, patent or patent application was specifically and individually noted when referenced that it is to be incorporated herein by reference. In addition, citation or identification of any reference in this application shall not be construed as an admission that such reference is available as prior art to the present invention. To the extent that section headings are used, they should not be construed as necessarily limiting. In addition, any priority document(s) of this application is/are hereby incorporated herein by reference in its/their entirety. 

What is claimed is:
 1. A method of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance, and/or reducing time to flowering or time to inflorescence emergence of a plant, comprising over-expressing within the plant a polypeptide comprising an amino acid sequence at least 80% identical to SEQ ID NO: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or 4682 as compared to a native plant under the same growth conditions, thereby increasing the nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance, and/or reducing the time to flowering or the time to inflorescence emergence of the plant.
 2. The method of claim 1, wherein said polypeptide is at least 90% identical to SEQ ID NO: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or
 4682. 3. The method of claim 1, wherein said polypeptide is at least 95% identical to SEQ ID NO: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or
 4682. 4. The method of claim 1, wherein said polypeptide is set forth in SEQ ID NO: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or
 4682. 5. The method of claim 1, wherein said polypeptide is expressed from an exogenous polynucleotide comprising a nucleic acid sequence at least 80% identical to the nucleic acid sequence set forth in SEQ ID NO:1-95, 97-166, 168-210, 212-234, 236-351, 353-364, 366-419, 421-462, 464-467, 785-2282, 2284-2729, 2734-3046 or
 3047. 6. The method of claim 1, wherein said polypeptide is expressed from an exogenous polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-95, 97-166, 168-210, 212-234, 236-351, 353-364, 366-419, 421-462, 464-467, 785-2282, 2284-2729, and 2734-3047.
 7. The method of claim 1, further comprising growing the plant over-expressing said polypeptide under the abiotic stress.
 8. The method of claim 1, wherein said abiotic stress is selected from the group consisting of salinity, drought, osmotic stress, water deprivation, flood, etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nutrient excess, atmospheric pollution and UV irradiation.
 9. A method of producing seeds of a crop, comprising: (a) selecting a parent plant being transformed with an exogenous polynucleotide encoding a polypeptide comprising an amino acid sequence which exhibits at least 80% sequence identity to the polypeptide selected from the group consisting of SEQ ID NOs: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or 4682, wherein said parent plant exhibits an increased trait selected from the group consisting of: nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and abiotic stress tolerance, and/or a reduced trait selected from the group of time to flowering and time to inflorescence emergence, as compared to a non-transformed plant which is grown under the same growth conditions, and; (b) growing a seed-producing plant from said parent plant resultant of step (a), wherein said seed-producing plant which comprises said exogenous polynucleotide has said increased trait, and/or said reduced trait, and; (c) producing seeds from said seed-producing plant resultant of step (b), thereby producing seeds of the crop.
 10. The method of claim 9, wherein said polypeptide is set forth in SEQ ID NO: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or
 4682. 11. The method of claim 1, further comprising selecting a plant over-expressing said polypeptide for an increased nitrogen use efficiency, an increased yield, an increased biomass, an increased growth rate, an increased vigor, an increased oil content, an increased fiber yield, an increased fiber quality, an increased abiotic stress tolerance, a reduced time to flowering and/or a reduced time to inflorescence emergence, as compared to a non-transformed plant grown under the same growth conditions.
 12. The method of claim 11, wherein said selecting is performed under non-stress conditions.
 13. The method of claim 11, wherein said selecting is performed under abiotic stress conditions.
 14. A nucleic acid construct comprising an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises an amino acid sequence at least 80% identical to the amino acid sequence set forth in SEQ ID NO: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, 4414-4681 or 4682 and a promoter for directing transcription of said nucleic acid sequence in a host cell, wherein said promoter is heterologous to said isolated polynucleotide, and wherein said amino acid sequence is capable of increasing nitrogen use efficiency, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or abiotic stress tolerance and/or reducing time to flowering or reducing time to inflorescence emergence of the plant.
 15. The nucleic acid construct of claim 14, wherein said amino acid sequence is selected from the group consisting of SEQ ID NOs: 468-562, 564-633, 635-677, 679-748, 750-784, 3048-4039, 4041-4333, 4335-4410, and 4414-4682.
 16. The nucleic acid construct of claim 14, wherein said isolated polynucleotide comprises a nucleic acid sequence at least 80% identical to the nucleic acid sequence set forth in SEQ ID NO: 1-95, 97-166, 168-210, 212-234, 236-351, 353-364, 366-419, 421-462, 464-467, 785-2282, 2284-2729, 2734-3046 or
 3047. 17. The nucleic acid construct of claim 14, wherein said isolated polynucleotide comprises a nucleic acid sequence as set forth in SEQ ID NO: 1-95, 97-166, 168-210, 212-234, 236-351, 353-364, 366-419, 421-462, 464-467, 785-2282, 2284-2729, 2734-3046 or
 3047. 18. A plant cell comprising the nucleic acid construct of claim
 14. 19. The plant cell of claim 18, wherein the plant cell forms part of a plant.
 20. A transgenic plant comprising the nucleic acid construct of claim
 14. 21. A method of growing a crop, the method comprising seeding seeds and/or planting plantlets of a plant transformed with the nucleic acid construct of claim 14, wherein the plant is obtained from plants which have been transformed with said isolated polynucleotide and which have been selected for at least one trait selected from the group consisting of: increased nitrogen use efficiency, increased yield, increased biomass, increased growth rate, increased vigor, increased oil content, increased fiber yield, increased fiber quality, increased abiotic stress tolerance, reduced time to flowering and reduced time to inflorescence emergence, as compared to a non-transformed plant which is grown under the same growth conditions, thereby growing the crop. 